/* * Copyright 2011 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkPDFDevice.h" #include "SkAdvancedTypefaceMetrics.h" #include "SkAnnotationKeys.h" #include "SkBitmapDevice.h" #include "SkBitmapKey.h" #include "SkCanvas.h" #include "SkClipOpPriv.h" #include "SkClusterator.h" #include "SkColor.h" #include "SkColorFilter.h" #include "SkDraw.h" #include "SkGlyphCache.h" #include "SkGlyphRun.h" #include "SkImageFilterCache.h" #include "SkJpegEncoder.h" #include "SkMakeUnique.h" #include "SkMaskFilterBase.h" #include "SkPDFBitmap.h" #include "SkPDFCanon.h" #include "SkPDFDocument.h" #include "SkPDFFont.h" #include "SkPDFFormXObject.h" #include "SkPDFGraphicState.h" #include "SkPDFResourceDict.h" #include "SkPDFShader.h" #include "SkPDFTypes.h" #include "SkPDFUtils.h" #include "SkPath.h" #include "SkPathEffect.h" #include "SkPathOps.h" #include "SkPixelRef.h" #include "SkRRect.h" #include "SkRasterClip.h" #include "SkScopeExit.h" #include "SkString.h" #include "SkSurface.h" #include "SkTemplates.h" #include "SkTextBlob.h" #include "SkTextFormatParams.h" #include "SkTo.h" #include "SkUtils.h" #include "SkXfermodeInterpretation.h" #ifndef SK_PDF_MASK_QUALITY // If MASK_QUALITY is in [0,100], will be used for JpegEncoder. // Otherwise, just encode masks losslessly. #define SK_PDF_MASK_QUALITY 50 // Since these masks are used for blurry shadows, we shouldn't need // high quality. Raise this value if your shadows have visible JPEG // artifacts. // If SkJpegEncoder::Encode fails, we will fall back to the lossless // encoding. #endif // Utility functions // This function destroys the mask and either frees or takes the pixels. sk_sp mask_to_greyscale_image(SkMask* mask) { sk_sp img; SkPixmap pm(SkImageInfo::Make(mask->fBounds.width(), mask->fBounds.height(), kGray_8_SkColorType, kOpaque_SkAlphaType), mask->fImage, mask->fRowBytes); const int imgQuality = SK_PDF_MASK_QUALITY; if (imgQuality <= 100 && imgQuality >= 0) { SkDynamicMemoryWStream buffer; SkJpegEncoder::Options jpegOptions; jpegOptions.fQuality = imgQuality; if (SkJpegEncoder::Encode(&buffer, pm, jpegOptions)) { img = SkImage::MakeFromEncoded(buffer.detachAsData()); SkASSERT(img); if (img) { SkMask::FreeImage(mask->fImage); } } } if (!img) { img = SkImage::MakeFromRaster(pm, [](const void* p, void*) { SkMask::FreeImage((void*)p); }, nullptr); } *mask = SkMask(); // destructive; return img; } sk_sp alpha_image_to_greyscale_image(const SkImage* mask) { int w = mask->width(), h = mask->height(); SkBitmap greyBitmap; greyBitmap.allocPixels(SkImageInfo::Make(w, h, kGray_8_SkColorType, kOpaque_SkAlphaType)); if (!mask->readPixels(SkImageInfo::MakeA8(w, h), greyBitmap.getPixels(), greyBitmap.rowBytes(), 0, 0)) { return nullptr; } return SkImage::MakeFromBitmap(greyBitmap); } static void draw_points(SkCanvas::PointMode mode, size_t count, const SkPoint* points, const SkPaint& paint, const SkIRect& bounds, const SkMatrix& ctm, SkBaseDevice* device) { SkRasterClip rc(bounds); SkDraw draw; draw.fDst = SkPixmap(SkImageInfo::MakeUnknown(bounds.right(), bounds.bottom()), nullptr, 0); draw.fMatrix = &ctm; draw.fRC = &rc; draw.drawPoints(mode, count, points, paint, device); } // If the paint will definitely draw opaquely, replace kSrc with // kSrcOver. http://crbug.com/473572 static void replace_srcmode_on_opaque_paint(SkPaint* paint) { if (kSrcOver_SkXfermodeInterpretation == SkInterpretXfermode(*paint, false)) { paint->setBlendMode(SkBlendMode::kSrcOver); } } // A shader's matrix is: CTMM x LocalMatrix x WrappingLocalMatrix. We want to // switch to device space, where CTM = I, while keeping the original behavior. // // I * LocalMatrix * NewWrappingMatrix = CTM * LocalMatrix // LocalMatrix * NewWrappingMatrix = CTM * LocalMatrix // InvLocalMatrix * LocalMatrix * NewWrappingMatrix = InvLocalMatrix * CTM * LocalMatrix // NewWrappingMatrix = InvLocalMatrix * CTM * LocalMatrix // static void transform_shader(SkPaint* paint, const SkMatrix& ctm) { SkMatrix lm = SkPDFUtils::GetShaderLocalMatrix(paint->getShader()); SkMatrix lmInv; if (lm.invert(&lmInv)) { SkMatrix m = SkMatrix::Concat(SkMatrix::Concat(lmInv, ctm), lm); paint->setShader(paint->getShader()->makeWithLocalMatrix(m)); } } static void emit_pdf_color(SkColor color, SkWStream* result) { SkASSERT(SkColorGetA(color) == 0xFF); // We handle alpha elsewhere. SkPDFUtils::AppendColorComponent(SkColorGetR(color), result); result->writeText(" "); SkPDFUtils::AppendColorComponent(SkColorGetG(color), result); result->writeText(" "); SkPDFUtils::AppendColorComponent(SkColorGetB(color), result); result->writeText(" "); } static SkPaint calculate_text_paint(const SkPaint& paint) { SkPaint result = paint; if (result.isFakeBoldText()) { SkScalar fakeBoldScale = SkScalarInterpFunc(result.getTextSize(), kStdFakeBoldInterpKeys, kStdFakeBoldInterpValues, kStdFakeBoldInterpLength); SkScalar width = result.getTextSize() * fakeBoldScale; if (result.getStyle() == SkPaint::kFill_Style) { result.setStyle(SkPaint::kStrokeAndFill_Style); } else { width += result.getStrokeWidth(); } result.setStrokeWidth(width); } return result; } // If the paint has a color filter, apply the color filter to the shader or the // paint color. Remove the color filter. void remove_color_filter(SkPaint* paint) { if (SkColorFilter* cf = paint->getColorFilter()) { if (SkShader* shader = paint->getShader()) { paint->setShader(shader->makeWithColorFilter(paint->refColorFilter())); } else { paint->setColor(cf->filterColor(paint->getColor())); } paint->setColorFilter(nullptr); } } SkPDFDevice::GraphicStateEntry::GraphicStateEntry() : fColor(SK_ColorBLACK) , fTextScaleX(SK_Scalar1) , fTextFill(SkPaint::kFill_Style) , fShaderIndex(-1) , fGraphicStateIndex(-1) { fMatrix.reset(); } bool SkPDFDevice::GraphicStateEntry::compareInitialState( const GraphicStateEntry& cur) { return fColor == cur.fColor && fShaderIndex == cur.fShaderIndex && fGraphicStateIndex == cur.fGraphicStateIndex && fMatrix == cur.fMatrix && fClipStack == cur.fClipStack && (fTextScaleX == 0 || (fTextScaleX == cur.fTextScaleX && fTextFill == cur.fTextFill)); } class GraphicStackState { public: GraphicStackState(const SkClipStack& existingClipStack, SkWStream* contentStream) : fStackDepth(0), fContentStream(contentStream) { fEntries[0].fClipStack = existingClipStack; } void updateClip(const SkClipStack& clipStack, const SkIRect& bounds); void updateMatrix(const SkMatrix& matrix); void updateDrawingState(const SkPDFDevice::GraphicStateEntry& state); void drainStack(); private: void push(); void pop(); SkPDFDevice::GraphicStateEntry* currentEntry() { return &fEntries[fStackDepth]; } // Conservative limit on save depth, see impl. notes in PDF 1.4 spec. static const int kMaxStackDepth = 12; SkPDFDevice::GraphicStateEntry fEntries[kMaxStackDepth + 1]; int fStackDepth; SkWStream* fContentStream; }; void GraphicStackState::drainStack() { while (fStackDepth) { pop(); } } void GraphicStackState::push() { SkASSERT(fStackDepth < kMaxStackDepth); fContentStream->writeText("q\n"); fStackDepth++; fEntries[fStackDepth] = fEntries[fStackDepth - 1]; } void GraphicStackState::pop() { SkASSERT(fStackDepth > 0); fContentStream->writeText("Q\n"); fStackDepth--; } /* Calculate an inverted path's equivalent non-inverted path, given the * canvas bounds. * outPath may alias with invPath (since this is supported by PathOps). */ static bool calculate_inverse_path(const SkRect& bounds, const SkPath& invPath, SkPath* outPath) { SkASSERT(invPath.isInverseFillType()); SkPath clipPath; clipPath.addRect(bounds); return Op(clipPath, invPath, kIntersect_SkPathOp, outPath); } bool apply_clip(SkClipOp op, const SkPath& u, const SkPath& v, SkPath* r) { switch (op) { case SkClipOp::kDifference: return Op(u, v, kDifference_SkPathOp, r); case SkClipOp::kIntersect: return Op(u, v, kIntersect_SkPathOp, r); #ifdef SK_SUPPORT_DEPRECATED_CLIPOPS case SkClipOp::kUnion_deprecated: return Op(u, v, kUnion_SkPathOp, r); case SkClipOp::kXOR_deprecated: return Op(u, v, kXOR_SkPathOp, r); case SkClipOp::kReverseDifference_deprecated: return Op(u, v, kReverseDifference_SkPathOp, r); case SkClipOp::kReplace_deprecated: *r = v; return true; #endif default: return false; } } static SkRect rect_intersect(SkRect u, SkRect v) { if (u.isEmpty() || v.isEmpty()) { return {0, 0, 0, 0}; } return u.intersect(v) ? u : SkRect{0, 0, 0, 0}; } // Test to see if the clipstack is a simple rect, If so, we can avoid all PathOps code // and speed thing up. static bool is_rect(const SkClipStack& clipStack, const SkRect& bounds, SkRect* dst) { SkRect currentClip = bounds; SkClipStack::Iter iter(clipStack, SkClipStack::Iter::kBottom_IterStart); while (const SkClipStack::Element* element = iter.next()) { SkRect elementRect{0, 0, 0, 0}; switch (element->getDeviceSpaceType()) { case SkClipStack::Element::DeviceSpaceType::kEmpty: break; case SkClipStack::Element::DeviceSpaceType::kRect: elementRect = element->getDeviceSpaceRect(); break; default: return false; } switch (element->getOp()) { case kReplace_SkClipOp: currentClip = rect_intersect(bounds, elementRect); break; case SkClipOp::kIntersect: currentClip = rect_intersect(currentClip, elementRect); break; default: return false; } } *dst = currentClip; return true; } static void append_clip(const SkClipStack& clipStack, const SkIRect& bounds, SkWStream* wStream) { // The bounds are slightly outset to ensure this is correct in the // face of floating-point accuracy and possible SkRegion bitmap // approximations. SkRect outsetBounds = SkRect::Make(bounds.makeOutset(1, 1)); SkRect clipStackRect; if (is_rect(clipStack, outsetBounds, &clipStackRect)) { SkPDFUtils::AppendRectangle(clipStackRect, wStream); wStream->writeText("W* n\n"); return; } SkPath clipPath; (void)clipStack.asPath(&clipPath); SkPath clipBoundsPath; clipBoundsPath.addRect(outsetBounds); if (Op(clipPath, clipBoundsPath, kIntersect_SkPathOp, &clipPath)) { SkPDFUtils::EmitPath(clipPath, SkPaint::kFill_Style, wStream); SkPath::FillType clipFill = clipPath.getFillType(); NOT_IMPLEMENTED(clipFill == SkPath::kInverseEvenOdd_FillType, false); NOT_IMPLEMENTED(clipFill == SkPath::kInverseWinding_FillType, false); if (clipFill == SkPath::kEvenOdd_FillType) { wStream->writeText("W* n\n"); } else { wStream->writeText("W n\n"); } } // If Op() fails (pathological case; e.g. input values are // extremely large or NaN), emit no clip at all. } // TODO(vandebo): Take advantage of SkClipStack::getSaveCount(), the PDF // graphic state stack, and the fact that we can know all the clips used // on the page to optimize this. void GraphicStackState::updateClip(const SkClipStack& clipStack, const SkIRect& bounds) { if (clipStack == currentEntry()->fClipStack) { return; } while (fStackDepth > 0) { pop(); if (clipStack == currentEntry()->fClipStack) { return; } } push(); currentEntry()->fClipStack = clipStack; append_clip(clipStack, bounds, fContentStream); } void GraphicStackState::updateMatrix(const SkMatrix& matrix) { if (matrix == currentEntry()->fMatrix) { return; } if (currentEntry()->fMatrix.getType() != SkMatrix::kIdentity_Mask) { SkASSERT(fStackDepth > 0); SkASSERT(fEntries[fStackDepth].fClipStack == fEntries[fStackDepth -1].fClipStack); pop(); SkASSERT(currentEntry()->fMatrix.getType() == SkMatrix::kIdentity_Mask); } if (matrix.getType() == SkMatrix::kIdentity_Mask) { return; } push(); SkPDFUtils::AppendTransform(matrix, fContentStream); currentEntry()->fMatrix = matrix; } void GraphicStackState::updateDrawingState(const SkPDFDevice::GraphicStateEntry& state) { // PDF treats a shader as a color, so we only set one or the other. if (state.fShaderIndex >= 0) { if (state.fShaderIndex != currentEntry()->fShaderIndex) { SkPDFUtils::ApplyPattern(state.fShaderIndex, fContentStream); currentEntry()->fShaderIndex = state.fShaderIndex; } } else { if (state.fColor != currentEntry()->fColor || currentEntry()->fShaderIndex >= 0) { emit_pdf_color(state.fColor, fContentStream); fContentStream->writeText("RG "); emit_pdf_color(state.fColor, fContentStream); fContentStream->writeText("rg\n"); currentEntry()->fColor = state.fColor; currentEntry()->fShaderIndex = -1; } } if (state.fGraphicStateIndex != currentEntry()->fGraphicStateIndex) { SkPDFUtils::ApplyGraphicState(state.fGraphicStateIndex, fContentStream); currentEntry()->fGraphicStateIndex = state.fGraphicStateIndex; } if (state.fTextScaleX) { if (state.fTextScaleX != currentEntry()->fTextScaleX) { SkScalar pdfScale = state.fTextScaleX * 100; SkPDFUtils::AppendScalar(pdfScale, fContentStream); fContentStream->writeText(" Tz\n"); currentEntry()->fTextScaleX = state.fTextScaleX; } if (state.fTextFill != currentEntry()->fTextFill) { static_assert(SkPaint::kFill_Style == 0, "enum_must_match_value"); static_assert(SkPaint::kStroke_Style == 1, "enum_must_match_value"); static_assert(SkPaint::kStrokeAndFill_Style == 2, "enum_must_match_value"); fContentStream->writeDecAsText(state.fTextFill); fContentStream->writeText(" Tr\n"); currentEntry()->fTextFill = state.fTextFill; } } } static bool not_supported_for_layers(const SkPaint& layerPaint) { // PDF does not support image filters, so render them on CPU. // Note that this rendering is done at "screen" resolution (100dpi), not // printer resolution. // TODO: It may be possible to express some filters natively using PDF // to improve quality and file size (https://bug.skia.org/3043) // TODO: should we return true if there is a colorfilter? return layerPaint.getImageFilter() != nullptr; } SkBaseDevice* SkPDFDevice::onCreateDevice(const CreateInfo& cinfo, const SkPaint* layerPaint) { if (layerPaint && not_supported_for_layers(*layerPaint)) { // need to return a raster device, which we will detect in drawDevice() return SkBitmapDevice::Create(cinfo.fInfo, SkSurfaceProps(0, kUnknown_SkPixelGeometry)); } return new SkPDFDevice(cinfo.fInfo.dimensions(), fDocument); } SkPDFCanon* SkPDFDevice::getCanon() const { return fDocument->canon(); } // A helper class to automatically finish a ContentEntry at the end of a // drawing method and maintain the state needed between set up and finish. class ScopedContentEntry { public: ScopedContentEntry(SkPDFDevice* device, const SkClipStack& clipStack, const SkMatrix& matrix, const SkPaint& paint, bool hasText = false) : fDevice(device) , fContentEntry(nullptr) , fBlendMode(SkBlendMode::kSrcOver) , fDstFormXObject(nullptr) { if (matrix.hasPerspective()) { NOT_IMPLEMENTED(!matrix.hasPerspective(), false); return; } fBlendMode = paint.getBlendMode(); fContentEntry = fDevice->setUpContentEntry(clipStack, matrix, paint, hasText, &fDstFormXObject); } ScopedContentEntry(SkPDFDevice* dev, const SkPaint& paint, bool hasText = false) : ScopedContentEntry(dev, dev->cs(), dev->ctm(), paint, hasText) {} ~ScopedContentEntry() { if (fContentEntry) { SkPath* shape = &fShape; if (shape->isEmpty()) { shape = nullptr; } fDevice->finishContentEntry(fBlendMode, std::move(fDstFormXObject), shape); } } SkPDFDevice::ContentEntry* entry() { return fContentEntry; } SkDynamicMemoryWStream* stream() { return &fContentEntry->fContent; } /* Returns true when we explicitly need the shape of the drawing. */ bool needShape() { switch (fBlendMode) { case SkBlendMode::kClear: case SkBlendMode::kSrc: case SkBlendMode::kSrcIn: case SkBlendMode::kSrcOut: case SkBlendMode::kDstIn: case SkBlendMode::kDstOut: case SkBlendMode::kSrcATop: case SkBlendMode::kDstATop: case SkBlendMode::kModulate: return true; default: return false; } } /* Returns true unless we only need the shape of the drawing. */ bool needSource() { if (fBlendMode == SkBlendMode::kClear) { return false; } return true; } /* If the shape is different than the alpha component of the content, then * setShape should be called with the shape. In particular, images and * devices have rectangular shape. */ void setShape(const SkPath& shape) { fShape = shape; } private: SkPDFDevice* fDevice; SkPDFDevice::ContentEntry* fContentEntry; SkBlendMode fBlendMode; sk_sp fDstFormXObject; SkPath fShape; }; //////////////////////////////////////////////////////////////////////////////// SkPDFDevice::SkPDFDevice(SkISize pageSize, SkPDFDocument* doc) : INHERITED(SkImageInfo::MakeUnknown(pageSize.width(), pageSize.height()), SkSurfaceProps(0, kUnknown_SkPixelGeometry)) , fPageSize(pageSize) , fInitialTransform(SkMatrix::I()) , fDocument(doc) { SkASSERT(!pageSize.isEmpty()); } void SkPDFDevice::setFlip() { // Skia generally uses the top left as the origin but PDF // natively has the origin at the bottom left. This matrix // corrects for that. But that only needs to be done once, we // don't do it when layering. SkScalar rasterScale = SkPDFUtils::kDpiForRasterScaleOne / fDocument->rasterDpi(); fInitialTransform.setConcat(SkMatrix::MakeScale(rasterScale, -rasterScale), SkMatrix::MakeTrans(0, -fPageSize.fHeight)); } SkPDFDevice::~SkPDFDevice() { this->cleanUp(); } void SkPDFDevice::init() { fContentEntries.reset(); } void SkPDFDevice::cleanUp() { fGraphicStateResources.unrefAll(); fXObjectResources.unrefAll(); fFontResources.unrefAll(); fShaderResources.unrefAll(); } void SkPDFDevice::drawAnnotation(const SkRect& rect, const char key[], SkData* value) { if (!value) { return; } if (rect.isEmpty()) { if (!strcmp(SkAnnotationKeys::Define_Named_Dest_Key(), key)) { SkPoint transformedPoint; this->ctm().mapXY(rect.x(), rect.y(), &transformedPoint); fNamedDestinations.emplace_back(NamedDestination{sk_ref_sp(value), transformedPoint}); } return; } // Convert to path to handle non-90-degree rotations. SkPath path; path.addRect(rect); path.transform(this->ctm(), &path); SkPath clip; (void)this->cs().asPath(&clip); Op(clip, path, kIntersect_SkPathOp, &path); // PDF wants a rectangle only. SkRect transformedRect = path.getBounds(); if (transformedRect.isEmpty()) { return; } if (!strcmp(SkAnnotationKeys::URL_Key(), key)) { fLinkToURLs.emplace_back(RectWithData{transformedRect, sk_ref_sp(value)}); } else if (!strcmp(SkAnnotationKeys::Link_Named_Dest_Key(), key)) { fLinkToDestinations.emplace_back(RectWithData{transformedRect, sk_ref_sp(value)}); } } void SkPDFDevice::drawPaint(const SkPaint& srcPaint) { if (this->hasEmptyClip()) { return; } SkPaint newPaint = srcPaint; remove_color_filter(&newPaint); replace_srcmode_on_opaque_paint(&newPaint); newPaint.setStyle(SkPaint::kFill_Style); SkMatrix ctm = this->ctm(); if (ctm.getType() & SkMatrix::kPerspective_Mask) { if (newPaint.getShader()) { transform_shader(&newPaint, ctm); } ctm = SkMatrix::I(); } ScopedContentEntry content(this, this->cs(), ctm, newPaint); this->internalDrawPaint(newPaint, content.entry()); } void SkPDFDevice::internalDrawPaint(const SkPaint& paint, SkPDFDevice::ContentEntry* contentEntry) { if (!contentEntry) { return; } SkRect bbox = SkRect::Make(fPageSize); SkMatrix inverse; if (!contentEntry->fState.fMatrix.invert(&inverse)) { return; } inverse.mapRect(&bbox); SkPDFUtils::AppendRectangle(bbox, &contentEntry->fContent); SkPDFUtils::PaintPath(paint.getStyle(), SkPath::kWinding_FillType, &contentEntry->fContent); } void SkPDFDevice::drawPoints(SkCanvas::PointMode mode, size_t count, const SkPoint* points, const SkPaint& srcPaint) { if (this->hasEmptyClip()) { return; } SkPaint passedPaint = srcPaint; remove_color_filter(&passedPaint); replace_srcmode_on_opaque_paint(&passedPaint); if (SkCanvas::kPoints_PointMode != mode) { passedPaint.setStyle(SkPaint::kStroke_Style); } if (count == 0) { return; } // SkDraw::drawPoints converts to multiple calls to fDevice->drawPath. // We only use this when there's a path effect because of the overhead // of multiple calls to setUpContentEntry it causes. if (passedPaint.getPathEffect()) { draw_points(mode, count, points, passedPaint, this->devClipBounds(), this->ctm(), this); return; } const SkPaint* paint = &passedPaint; SkPaint modifiedPaint; if (mode == SkCanvas::kPoints_PointMode && paint->getStrokeCap() != SkPaint::kRound_Cap) { modifiedPaint = *paint; paint = &modifiedPaint; if (paint->getStrokeWidth()) { // PDF won't draw a single point with square/butt caps because the // orientation is ambiguous. Draw a rectangle instead. modifiedPaint.setStyle(SkPaint::kFill_Style); SkScalar strokeWidth = paint->getStrokeWidth(); SkScalar halfStroke = SkScalarHalf(strokeWidth); for (size_t i = 0; i < count; i++) { SkRect r = SkRect::MakeXYWH(points[i].fX, points[i].fY, 0, 0); r.inset(-halfStroke, -halfStroke); this->drawRect(r, modifiedPaint); } return; } else { modifiedPaint.setStrokeCap(SkPaint::kRound_Cap); } } ScopedContentEntry content(this, *paint); if (!content.entry()) { return; } SkDynamicMemoryWStream* contentStream = content.stream(); switch (mode) { case SkCanvas::kPolygon_PointMode: SkPDFUtils::MoveTo(points[0].fX, points[0].fY, contentStream); for (size_t i = 1; i < count; i++) { SkPDFUtils::AppendLine(points[i].fX, points[i].fY, contentStream); } SkPDFUtils::StrokePath(contentStream); break; case SkCanvas::kLines_PointMode: for (size_t i = 0; i < count/2; i++) { SkPDFUtils::MoveTo(points[i * 2].fX, points[i * 2].fY, contentStream); SkPDFUtils::AppendLine(points[i * 2 + 1].fX, points[i * 2 + 1].fY, contentStream); SkPDFUtils::StrokePath(contentStream); } break; case SkCanvas::kPoints_PointMode: SkASSERT(paint->getStrokeCap() == SkPaint::kRound_Cap); for (size_t i = 0; i < count; i++) { SkPDFUtils::MoveTo(points[i].fX, points[i].fY, contentStream); SkPDFUtils::ClosePath(contentStream); SkPDFUtils::StrokePath(contentStream); } break; default: SkASSERT(false); } } static sk_sp create_link_annotation(const SkRect& translatedRect) { auto annotation = sk_make_sp("Annot"); annotation->insertName("Subtype", "Link"); annotation->insertInt("F", 4); // required by ISO 19005 auto border = sk_make_sp(); border->reserve(3); border->appendInt(0); // Horizontal corner radius. border->appendInt(0); // Vertical corner radius. border->appendInt(0); // Width, 0 = no border. annotation->insertObject("Border", std::move(border)); auto rect = sk_make_sp(); rect->reserve(4); rect->appendScalar(translatedRect.fLeft); rect->appendScalar(translatedRect.fTop); rect->appendScalar(translatedRect.fRight); rect->appendScalar(translatedRect.fBottom); annotation->insertObject("Rect", std::move(rect)); return annotation; } static sk_sp create_link_to_url(const SkData* urlData, const SkRect& r) { sk_sp annotation = create_link_annotation(r); SkString url(static_cast(urlData->data()), urlData->size() - 1); auto action = sk_make_sp("Action"); action->insertName("S", "URI"); action->insertString("URI", url); annotation->insertObject("A", std::move(action)); return annotation; } static sk_sp create_link_named_dest(const SkData* nameData, const SkRect& r) { sk_sp annotation = create_link_annotation(r); SkString name(static_cast(nameData->data()), nameData->size() - 1); annotation->insertName("Dest", name); return annotation; } void SkPDFDevice::drawRect(const SkRect& rect, const SkPaint& srcPaint) { if (this->hasEmptyClip()) { return; } SkPaint paint = srcPaint; remove_color_filter(&paint); replace_srcmode_on_opaque_paint(&paint); SkRect r = rect; r.sort(); if (paint.getPathEffect() || paint.getMaskFilter()) { SkPath path; path.addRect(r); this->drawPath(path, paint, nullptr, true); return; } ScopedContentEntry content(this, paint); if (!content.entry()) { return; } SkPDFUtils::AppendRectangle(r, content.stream()); SkPDFUtils::PaintPath(paint.getStyle(), SkPath::kWinding_FillType, content.stream()); } void SkPDFDevice::drawRRect(const SkRRect& rrect, const SkPaint& srcPaint) { if (this->hasEmptyClip()) { return; } SkPaint paint = srcPaint; remove_color_filter(&paint); replace_srcmode_on_opaque_paint(&paint); SkPath path; path.addRRect(rrect); this->drawPath(path, paint, nullptr, true); } void SkPDFDevice::drawOval(const SkRect& oval, const SkPaint& srcPaint) { if (this->hasEmptyClip()) { return; } SkPaint paint = srcPaint; remove_color_filter(&paint); replace_srcmode_on_opaque_paint(&paint); SkPath path; path.addOval(oval); this->drawPath(path, paint, nullptr, true); } void SkPDFDevice::drawPath(const SkPath& origPath, const SkPaint& srcPaint, const SkMatrix* prePathMatrix, bool pathIsMutable) { this->internalDrawPath( this->cs(), this->ctm(), origPath, srcPaint, prePathMatrix, pathIsMutable); } void SkPDFDevice::internalDrawPathWithFilter(const SkClipStack& clipStack, const SkMatrix& ctm, const SkPath& origPath, const SkPaint& origPaint, const SkMatrix* prePathMatrix) { SkASSERT(origPaint.getMaskFilter()); SkPath path(origPath); SkTCopyOnFirstWrite paint(origPaint); if (prePathMatrix) { path.transform(*prePathMatrix, &path); } SkStrokeRec::InitStyle initStyle = paint->getFillPath(path, &path) ? SkStrokeRec::kFill_InitStyle : SkStrokeRec::kHairline_InitStyle; path.transform(ctm, &path); SkIRect bounds = clipStack.bounds(this->bounds()).roundOut(); SkMask sourceMask; if (!SkDraw::DrawToMask(path, &bounds, paint->getMaskFilter(), &SkMatrix::I(), &sourceMask, SkMask::kComputeBoundsAndRenderImage_CreateMode, initStyle)) { return; } SkAutoMaskFreeImage srcAutoMaskFreeImage(sourceMask.fImage); SkMask dstMask; SkIPoint margin; if (!as_MFB(paint->getMaskFilter())->filterMask(&dstMask, sourceMask, ctm, &margin)) { return; } SkIRect dstMaskBounds = dstMask.fBounds; sk_sp mask = mask_to_greyscale_image(&dstMask); // PDF doesn't seem to allow masking vector graphics with an Image XObject. // Must mask with a Form XObject. sk_sp maskDevice = this->makeCongruentDevice(); { SkCanvas canvas(maskDevice); canvas.drawImage(mask, dstMaskBounds.x(), dstMaskBounds.y()); } if (!ctm.isIdentity() && paint->getShader()) { transform_shader(paint.writable(), ctm); // Since we are using identity matrix. } ScopedContentEntry content(this, clipStack, SkMatrix::I(), *paint); if (!content.entry()) { return; } this->addSMaskGraphicState(std::move(maskDevice), content.stream()); SkPDFUtils::AppendRectangle(SkRect::Make(dstMaskBounds), content.stream()); SkPDFUtils::PaintPath(SkPaint::kFill_Style, path.getFillType(), content.stream()); this->clearMaskOnGraphicState(content.stream()); } void SkPDFDevice::addSMaskGraphicState(sk_sp maskDevice, SkDynamicMemoryWStream* contentStream) { sk_sp sMaskGS = SkPDFGraphicState::GetSMaskGraphicState( maskDevice->makeFormXObjectFromDevice(true), false, SkPDFGraphicState::kLuminosity_SMaskMode, this->getCanon()); SkPDFUtils::ApplyGraphicState(this->addGraphicStateResource(sMaskGS.get()), contentStream); } void SkPDFDevice::clearMaskOnGraphicState(SkDynamicMemoryWStream* contentStream) { // The no-softmask graphic state is used to "turn off" the mask for later draw calls. sk_sp& noSMaskGS = this->getCanon()->fNoSmaskGraphicState; if (!noSMaskGS) { noSMaskGS = sk_make_sp("ExtGState"); noSMaskGS->insertName("SMask", "None"); } SkPDFUtils::ApplyGraphicState(this->addGraphicStateResource(noSMaskGS.get()), contentStream); } void SkPDFDevice::internalDrawPath(const SkClipStack& clipStack, const SkMatrix& ctm, const SkPath& origPath, const SkPaint& srcPaint, const SkMatrix* prePathMatrix, bool pathIsMutable) { if (clipStack.isEmpty(this->bounds())) { return; } SkPaint paint = srcPaint; remove_color_filter(&paint); replace_srcmode_on_opaque_paint(&paint); SkPath modifiedPath; SkPath* pathPtr = const_cast(&origPath); if (paint.getMaskFilter()) { this->internalDrawPathWithFilter(clipStack, ctm, origPath, paint, prePathMatrix); return; } SkMatrix matrix = ctm; if (prePathMatrix) { if (paint.getPathEffect() || paint.getStyle() != SkPaint::kFill_Style) { if (!pathIsMutable) { pathPtr = &modifiedPath; pathIsMutable = true; } origPath.transform(*prePathMatrix, pathPtr); } else { matrix.preConcat(*prePathMatrix); } } if (paint.getPathEffect()) { if (clipStack.isEmpty(this->bounds())) { return; } if (!pathIsMutable) { modifiedPath = origPath; pathPtr = &modifiedPath; pathIsMutable = true; } if (paint.getFillPath(*pathPtr, pathPtr)) { paint.setStyle(SkPaint::kFill_Style); } else { paint.setStyle(SkPaint::kStroke_Style); paint.setStrokeWidth(0); } paint.setPathEffect(nullptr); } if (this->handleInversePath(*pathPtr, paint, pathIsMutable, prePathMatrix)) { return; } if (matrix.getType() & SkMatrix::kPerspective_Mask) { if (!pathIsMutable) { modifiedPath = origPath; pathPtr = &modifiedPath; pathIsMutable = true; } pathPtr->transform(matrix); if (paint.getShader()) { transform_shader(&paint, matrix); } matrix = SkMatrix::I(); } ScopedContentEntry content(this, clipStack, matrix, paint); if (!content.entry()) { return; } constexpr SkScalar kToleranceScale = 0.0625f; // smaller = better conics (circles). SkScalar matrixScale = matrix.mapRadius(1.0f); SkScalar tolerance = matrixScale > 0.0f ? kToleranceScale / matrixScale : kToleranceScale; bool consumeDegeratePathSegments = paint.getStyle() == SkPaint::kFill_Style || (paint.getStrokeCap() != SkPaint::kRound_Cap && paint.getStrokeCap() != SkPaint::kSquare_Cap); SkPDFUtils::EmitPath(*pathPtr, paint.getStyle(), consumeDegeratePathSegments, content.stream(), tolerance); SkPDFUtils::PaintPath(paint.getStyle(), pathPtr->getFillType(), content.stream()); } //////////////////////////////////////////////////////////////////////////////// void SkPDFDevice::drawImageRect(const SkImage* image, const SkRect* src, const SkRect& dst, const SkPaint& paint, SkCanvas::SrcRectConstraint) { SkASSERT(image); this->internalDrawImageRect(SkKeyedImage(sk_ref_sp(const_cast(image))), src, dst, paint, this->ctm()); } void SkPDFDevice::drawBitmapRect(const SkBitmap& bm, const SkRect* src, const SkRect& dst, const SkPaint& paint, SkCanvas::SrcRectConstraint) { SkASSERT(!bm.drawsNothing()); this->internalDrawImageRect(SkKeyedImage(bm), src, dst, paint, this->ctm()); } void SkPDFDevice::drawBitmap(const SkBitmap& bm, SkScalar x, SkScalar y, const SkPaint& paint) { SkASSERT(!bm.drawsNothing()); auto r = SkRect::MakeXYWH(x, y, bm.width(), bm.height()); this->internalDrawImageRect(SkKeyedImage(bm), nullptr, r, paint, this->ctm()); } void SkPDFDevice::drawSprite(const SkBitmap& bm, int x, int y, const SkPaint& paint) { SkASSERT(!bm.drawsNothing()); auto r = SkRect::MakeXYWH(x, y, bm.width(), bm.height()); this->internalDrawImageRect(SkKeyedImage(bm), nullptr, r, paint, SkMatrix::I()); } void SkPDFDevice::drawImage(const SkImage* image, SkScalar x, SkScalar y, const SkPaint& paint) { SkASSERT(image); auto r = SkRect::MakeXYWH(x, y, image->width(), image->height()); this->internalDrawImageRect(SkKeyedImage(sk_ref_sp(const_cast(image))), nullptr, r, paint, this->ctm()); } //////////////////////////////////////////////////////////////////////////////// namespace { class GlyphPositioner { public: GlyphPositioner(SkDynamicMemoryWStream* content, SkScalar textSkewX, bool wideChars, SkPoint origin) : fContent(content) , fCurrentMatrixOrigin(origin) , fTextSkewX(textSkewX) , fWideChars(wideChars) { } ~GlyphPositioner() { this->flush(); } void flush() { if (fInText) { fContent->writeText("> Tj\n"); fInText = false; } } void writeGlyph(SkPoint xy, SkScalar advanceWidth, uint16_t glyph) { if (!fInitialized) { // Flip the text about the x-axis to account for origin swap and include // the passed parameters. fContent->writeText("1 0 "); SkPDFUtils::AppendScalar(-fTextSkewX, fContent); fContent->writeText(" -1 "); SkPDFUtils::AppendScalar(fCurrentMatrixOrigin.x(), fContent); fContent->writeText(" "); SkPDFUtils::AppendScalar(fCurrentMatrixOrigin.y(), fContent); fContent->writeText(" Tm\n"); fCurrentMatrixOrigin.set(0.0f, 0.0f); fInitialized = true; } SkPoint position = xy - fCurrentMatrixOrigin; if (position != SkPoint{fXAdvance, 0}) { this->flush(); SkPDFUtils::AppendScalar(position.x() - position.y() * fTextSkewX, fContent); fContent->writeText(" "); SkPDFUtils::AppendScalar(-position.y(), fContent); fContent->writeText(" Td "); fCurrentMatrixOrigin = xy; fXAdvance = 0; } fXAdvance += advanceWidth; if (!fInText) { fContent->writeText("<"); fInText = true; } if (fWideChars) { SkPDFUtils::WriteUInt16BE(fContent, glyph); } else { SkASSERT(0 == glyph >> 8); SkPDFUtils::WriteUInt8(fContent, static_cast(glyph)); } } private: SkDynamicMemoryWStream* fContent; SkPoint fCurrentMatrixOrigin; SkScalar fXAdvance = 0.0f; SkScalar fTextSkewX; bool fWideChars; bool fInText = false; bool fInitialized = false; }; } // namespace static SkUnichar map_glyph(const std::vector& glyphToUnicode, SkGlyphID glyph) { return glyph < glyphToUnicode.size() ? glyphToUnicode[SkToInt(glyph)] : -1; } static void update_font(SkWStream* wStream, int fontIndex, SkScalar textSize) { wStream->writeText("/"); char prefix = SkPDFResourceDict::GetResourceTypePrefix(SkPDFResourceDict::kFont_ResourceType); wStream->write(&prefix, 1); wStream->writeDecAsText(fontIndex); wStream->writeText(" "); SkPDFUtils::AppendScalar(textSize, wStream); wStream->writeText(" Tf\n"); } static void draw_glyph_run_as_path(SkPDFDevice* dev, const SkGlyphRun& glyphRun, SkPoint offset) { SkPath path; SkASSERT(glyphRun.paint().getTextEncoding() == SkPaint::kGlyphID_TextEncoding); glyphRun.paint().getPosTextPath(glyphRun.shuntGlyphsIDs().data(), glyphRun.shuntGlyphsIDs().size() * sizeof(SkGlyphID), glyphRun.positions().data(), &path); path.offset(offset.x(), offset.y()); dev->drawPath(path, glyphRun.paint(), nullptr, true); } static bool has_outline_glyph(SkGlyphID gid, SkGlyphCache* cache) { const SkGlyph& glyph = cache->getGlyphIDMetrics(gid); const SkPath* path = cache->findPath(glyph); return (path && !path->isEmpty()) || (glyph.fWidth == 0 && glyph.fHeight == 0); } static SkRect get_glyph_bounds_device_space(SkGlyphID gid, SkGlyphCache* cache, SkScalar xScale, SkScalar yScale, SkPoint xy, const SkMatrix& ctm) { const SkGlyph& glyph = cache->getGlyphIDMetrics(gid); SkRect glyphBounds = {glyph.fLeft * xScale, glyph.fTop * yScale, (glyph.fLeft + glyph.fWidth) * xScale, (glyph.fTop + glyph.fHeight) * yScale}; glyphBounds.offset(xy); ctm.mapRect(&glyphBounds); // now in dev space. return glyphBounds; } static bool contains(const SkRect& r, SkPoint p) { return r.left() <= p.x() && p.x() <= r.right() && r.top() <= p.y() && p.y() <= r.bottom(); } static sk_sp image_from_mask(const SkMask& mask) { if (!mask.fImage) { return nullptr; } SkIRect bounds = mask.fBounds; SkBitmap bm; switch (mask.fFormat) { case SkMask::kBW_Format: bm.allocPixels(SkImageInfo::MakeA8(bounds.width(), bounds.height())); for (int y = 0; y < bm.height(); ++y) { for (int x8 = 0; x8 < bm.width(); x8 += 8) { uint8_t v = *mask.getAddr1(x8 + bounds.x(), y + bounds.y()); int e = SkTMin(x8 + 8, bm.width()); for (int x = x8; x < e; ++x) { *bm.getAddr8(x, y) = (v >> (x & 0x7)) & 0x1 ? 0xFF : 0x00; } } } bm.setImmutable(); return SkImage::MakeFromBitmap(bm); case SkMask::kA8_Format: bm.installPixels(SkImageInfo::MakeA8(bounds.width(), bounds.height()), mask.fImage, mask.fRowBytes); return SkMakeImageFromRasterBitmap(bm, kAlways_SkCopyPixelsMode); case SkMask::kARGB32_Format: bm.installPixels(SkImageInfo::MakeN32Premul(bounds.width(), bounds.height()), mask.fImage, mask.fRowBytes); return SkMakeImageFromRasterBitmap(bm, kAlways_SkCopyPixelsMode); case SkMask::k3D_Format: SkASSERT(false); return nullptr; case SkMask::kLCD16_Format: SkASSERT(false); return nullptr; default: SkASSERT(false); return nullptr; } } void SkPDFDevice::internalDrawGlyphRun(const SkGlyphRun& glyphRun, SkPoint offset) { const SkGlyphID* glyphs = glyphRun.shuntGlyphsIDs().data(); uint32_t glyphCount = SkToU32(glyphRun.shuntGlyphsIDs().size()); const SkPaint& srcPaint = glyphRun.paint(); if (!glyphCount || !glyphs || srcPaint.getTextSize() <= 0 || this->hasEmptyClip()) { return; } if (srcPaint.getPathEffect() || srcPaint.getMaskFilter() || srcPaint.isVerticalText() || SkPaint::kFill_Style != srcPaint.getStyle()) { // Stroked Text doesn't work well with Type3 fonts. return draw_glyph_run_as_path(this, glyphRun, offset); } SkPaint paint = calculate_text_paint(srcPaint); remove_color_filter(&paint); replace_srcmode_on_opaque_paint(&paint); paint.setHinting(SkPaint::kNo_Hinting); if (!paint.getTypeface()) { paint.setTypeface(SkTypeface::MakeDefault()); } SkTypeface* typeface = paint.getTypeface(); if (!typeface) { SkDebugf("SkPDF: SkTypeface::MakeDefault() returned nullptr.\n"); return; } const SkAdvancedTypefaceMetrics* metrics = SkPDFFont::GetMetrics(typeface, fDocument->canon()); if (!metrics) { return; } const std::vector& glyphToUnicode = SkPDFFont::GetUnicodeMap( typeface, fDocument->canon()); SkClusterator clusterator(glyphRun); int emSize; auto glyphCache = SkPDFFont::MakeVectorCache(typeface, &emSize); SkScalar textSize = paint.getTextSize(); SkScalar advanceScale = textSize * paint.getTextScaleX() / emSize; // textScaleX and textScaleY are used to get a conservative bounding box for glyphs. SkScalar textScaleY = textSize / emSize; SkScalar textScaleX = advanceScale + paint.getTextSkewX() * textScaleY; SkASSERT(paint.getTextAlign() == SkPaint::kLeft_Align); SkRect clipStackBounds = this->cs().bounds(this->bounds()); struct PositionedGlyph { SkPoint fPos; SkGlyphID fGlyph; }; SkTArray missingGlyphs; { ScopedContentEntry content(this, paint, true); if (!content.entry()) { return; } SkDynamicMemoryWStream* out = content.stream(); out->writeText("BT\n"); SK_AT_SCOPE_EXIT(out->writeText("ET\n")); const SkGlyphID maxGlyphID = SkToU16(typeface->countGlyphs() - 1); bool multiByteGlyphs = SkPDFFont::IsMultiByte(SkPDFFont::FontType(*metrics)); if (clusterator.reversedChars()) { out->writeText("/ReversedChars BMC\n"); } SK_AT_SCOPE_EXIT(if (clusterator.reversedChars()) { out->writeText("EMC\n"); } ); GlyphPositioner glyphPositioner(out, paint.getTextSkewX(), multiByteGlyphs, offset); SkPDFFont* font = nullptr; while (SkClusterator::Cluster c = clusterator.next()) { int index = c.fGlyphIndex; int glyphLimit = index + c.fGlyphCount; bool actualText = false; SK_AT_SCOPE_EXIT(if (actualText) { glyphPositioner.flush(); out->writeText("EMC\n"); }); if (c.fUtf8Text) { // real cluster // Check if `/ActualText` needed. const char* textPtr = c.fUtf8Text; const char* textEnd = c.fUtf8Text + c.fTextByteLength; SkUnichar unichar = SkUTF8_NextUnicharWithError(&textPtr, textEnd); if (unichar < 0) { return; } if (textPtr < textEnd || // more characters left glyphLimit > index + 1 || // toUnicode wouldn't work unichar != map_glyph(glyphToUnicode, glyphs[index])) // test single Unichar map { glyphPositioner.flush(); out->writeText("/Span<writeText("> >> BDC\n"); // begin marked-content sequence // with an associated property list. actualText = true; } } for (; index < glyphLimit; ++index) { SkGlyphID gid = glyphs[index]; if (gid > maxGlyphID) { continue; } if (!font || !font->hasGlyph(gid)) { // Not yet specified font or need to switch font. int fontIndex = this->getFontResourceIndex(typeface, gid); // All preconditions for SkPDFFont::GetFontResource are met. SkASSERT(fontIndex >= 0); if (fontIndex < 0) { return; } glyphPositioner.flush(); update_font(out, fontIndex, textSize); font = fFontResources[fontIndex]; SkASSERT(font); // All preconditions for SkPDFFont::GetFontResource are met. if (!font) { return; } SkASSERT(font->multiByteGlyphs() == multiByteGlyphs); } SkPoint xy = glyphRun.positions()[index]; // Do a glyph-by-glyph bounds-reject if positions are absolute. SkRect glyphBounds = get_glyph_bounds_device_space( gid, glyphCache.get(), textScaleX, textScaleY, xy + offset, this->ctm()); if (glyphBounds.isEmpty()) { if (!contains(clipStackBounds, {glyphBounds.x(), glyphBounds.y()})) { continue; } } else { if (!clipStackBounds.intersects(glyphBounds)) { continue; // reject glyphs as out of bounds } } if (!has_outline_glyph(gid, glyphCache.get())) { missingGlyphs.push_back({xy + offset, gid}); } font->noteGlyphUsage(gid); SkGlyphID encodedGlyph = multiByteGlyphs ? gid : font->glyphToPDFFontEncoding(gid); SkScalar advance = advanceScale * glyphCache->getGlyphIDAdvance(gid).fAdvanceX; glyphPositioner.writeGlyph(xy, advance, encodedGlyph); } } } if (missingGlyphs.count() > 0) { // Fall back on images. SkPaint scaledGlyphCachePaint; scaledGlyphCachePaint.setTextSize(paint.getTextSize()); scaledGlyphCachePaint.setTextScaleX(paint.getTextScaleX()); scaledGlyphCachePaint.setTextSkewX(paint.getTextSkewX()); scaledGlyphCachePaint.setTypeface(sk_ref_sp(typeface)); auto scaledGlyphCache = SkStrikeCache::FindOrCreateStrikeExclusive(scaledGlyphCachePaint); SkTHashMap* map = &this->getCanon()->fBitmapGlyphImages; for (PositionedGlyph positionedGlyph : missingGlyphs) { SkPDFCanon::BitmapGlyphKey key = {typeface->uniqueID(), paint.getTextSize(), paint.getTextScaleX(), paint.getTextSkewX(), positionedGlyph.fGlyph, 0}; SkImage* img = nullptr; SkIPoint imgOffset = {0, 0}; if (SkPDFCanon::BitmapGlyph* ptr = map->find(key)) { img = ptr->fImage.get(); imgOffset = ptr->fOffset; } else { (void)scaledGlyphCache->findImage( scaledGlyphCache->getGlyphIDMetrics(positionedGlyph.fGlyph)); SkMask mask; scaledGlyphCache->getGlyphIDMetrics(positionedGlyph.fGlyph).toMask(&mask); imgOffset = {mask.fBounds.x(), mask.fBounds.y()}; img = map->set(key, {image_from_mask(mask), imgOffset})->fImage.get(); } if (img) { SkPoint pt = positionedGlyph.fPos + SkPoint{(SkScalar)imgOffset.x(), (SkScalar)imgOffset.y()}; this->drawImage(img, pt.x(), pt.y(), srcPaint); } } } } void SkPDFDevice::drawGlyphRunList(const SkGlyphRunList& glyphRunList) { for (const SkGlyphRun& glyphRun : glyphRunList) { this->internalDrawGlyphRun(glyphRun, glyphRunList.origin()); } } void SkPDFDevice::drawVertices(const SkVertices*, const SkMatrix*, int, SkBlendMode, const SkPaint&) { if (this->hasEmptyClip()) { return; } // TODO: implement drawVertices } void SkPDFDevice::drawDevice(SkBaseDevice* device, int x, int y, const SkPaint& paint) { SkASSERT(!paint.getImageFilter()); // Check if the source device is really a bitmapdevice (because that's what we returned // from createDevice (likely due to an imagefilter) SkPixmap pmap; if (device->peekPixels(&pmap)) { SkBitmap bitmap; bitmap.installPixels(pmap); this->drawSprite(bitmap, x, y, paint); return; } // our onCreateCompatibleDevice() always creates SkPDFDevice subclasses. SkPDFDevice* pdfDevice = static_cast(device); SkScalar scalarX = SkIntToScalar(x); SkScalar scalarY = SkIntToScalar(y); for (const RectWithData& l : pdfDevice->fLinkToURLs) { SkRect r = l.rect.makeOffset(scalarX, scalarY); fLinkToURLs.emplace_back(RectWithData{r, l.data}); } for (const RectWithData& l : pdfDevice->fLinkToDestinations) { SkRect r = l.rect.makeOffset(scalarX, scalarY); fLinkToDestinations.emplace_back(RectWithData{r, l.data}); } for (const NamedDestination& d : pdfDevice->fNamedDestinations) { SkPoint p = d.point + SkPoint::Make(scalarX, scalarY); fNamedDestinations.emplace_back(NamedDestination{d.nameData, p}); } if (pdfDevice->isContentEmpty()) { return; } SkMatrix matrix = SkMatrix::MakeTrans(SkIntToScalar(x), SkIntToScalar(y)); ScopedContentEntry content(this, this->cs(), matrix, paint); if (!content.entry()) { return; } if (content.needShape()) { SkPath shape; shape.addRect(SkRect::MakeXYWH(SkIntToScalar(x), SkIntToScalar(y), SkIntToScalar(device->width()), SkIntToScalar(device->height()))); content.setShape(shape); } if (!content.needSource()) { return; } sk_sp xObject = pdfDevice->makeFormXObjectFromDevice(); SkPDFUtils::DrawFormXObject(this->addXObjectResource(xObject.get()), content.stream()); } sk_sp SkPDFDevice::makeSurface(const SkImageInfo& info, const SkSurfaceProps& props) { return SkSurface::MakeRaster(info, &props); } sk_sp SkPDFDevice::makeResourceDict() const { SkTDArray fonts; fonts.setReserve(fFontResources.count()); for (SkPDFFont* font : fFontResources) { fonts.push(font); } return SkPDFResourceDict::Make( &fGraphicStateResources, &fShaderResources, &fXObjectResources, &fonts); } sk_sp SkPDFDevice::copyMediaBox() const { auto mediaBox = sk_make_sp(); mediaBox->reserve(4); mediaBox->appendInt(0); mediaBox->appendInt(0); mediaBox->appendInt(fPageSize.width()); mediaBox->appendInt(fPageSize.height()); return mediaBox; } std::unique_ptr SkPDFDevice::content() const { SkDynamicMemoryWStream buffer; if (fInitialTransform.getType() != SkMatrix::kIdentity_Mask) { SkPDFUtils::AppendTransform(fInitialTransform, &buffer); } GraphicStackState gsState(fExistingClipStack, &buffer); for (const auto& entry : fContentEntries) { gsState.updateClip(entry.fState.fClipStack, this->bounds()); gsState.updateMatrix(entry.fState.fMatrix); gsState.updateDrawingState(entry.fState); entry.fContent.writeToStream(&buffer); } gsState.drainStack(); if (buffer.bytesWritten() > 0) { return std::unique_ptr(buffer.detachAsStream()); } else { return skstd::make_unique(); } } /* Draws an inverse filled path by using Path Ops to compute the positive * inverse using the current clip as the inverse bounds. * Return true if this was an inverse path and was properly handled, * otherwise returns false and the normal drawing routine should continue, * either as a (incorrect) fallback or because the path was not inverse * in the first place. */ bool SkPDFDevice::handleInversePath(const SkPath& origPath, const SkPaint& paint, bool pathIsMutable, const SkMatrix* prePathMatrix) { if (!origPath.isInverseFillType()) { return false; } if (this->hasEmptyClip()) { return false; } SkPath modifiedPath; SkPath* pathPtr = const_cast(&origPath); SkPaint noInversePaint(paint); // Merge stroking operations into final path. if (SkPaint::kStroke_Style == paint.getStyle() || SkPaint::kStrokeAndFill_Style == paint.getStyle()) { bool doFillPath = paint.getFillPath(origPath, &modifiedPath); if (doFillPath) { noInversePaint.setStyle(SkPaint::kFill_Style); noInversePaint.setStrokeWidth(0); pathPtr = &modifiedPath; } else { // To be consistent with the raster output, hairline strokes // are rendered as non-inverted. modifiedPath.toggleInverseFillType(); this->drawPath(modifiedPath, paint, nullptr, true); return true; } } // Get bounds of clip in current transform space // (clip bounds are given in device space). SkMatrix transformInverse; SkMatrix totalMatrix = this->ctm(); if (prePathMatrix) { totalMatrix.preConcat(*prePathMatrix); } if (!totalMatrix.invert(&transformInverse)) { return false; } SkRect bounds = this->cs().bounds(this->bounds()); transformInverse.mapRect(&bounds); // Extend the bounds by the line width (plus some padding) // so the edge doesn't cause a visible stroke. bounds.outset(paint.getStrokeWidth() + SK_Scalar1, paint.getStrokeWidth() + SK_Scalar1); if (!calculate_inverse_path(bounds, *pathPtr, &modifiedPath)) { return false; } this->drawPath(modifiedPath, noInversePaint, prePathMatrix, true); return true; } void SkPDFDevice::appendAnnotations(SkPDFArray* array) const { array->reserve(fLinkToURLs.count() + fLinkToDestinations.count()); for (const RectWithData& rectWithURL : fLinkToURLs) { SkRect r; fInitialTransform.mapRect(&r, rectWithURL.rect); array->appendObjRef(create_link_to_url(rectWithURL.data.get(), r)); } for (const RectWithData& linkToDestination : fLinkToDestinations) { SkRect r; fInitialTransform.mapRect(&r, linkToDestination.rect); array->appendObjRef( create_link_named_dest(linkToDestination.data.get(), r)); } } void SkPDFDevice::appendDestinations(SkPDFDict* dict, SkPDFObject* page) const { for (const NamedDestination& dest : fNamedDestinations) { auto pdfDest = sk_make_sp(); pdfDest->reserve(5); pdfDest->appendObjRef(sk_ref_sp(page)); pdfDest->appendName("XYZ"); SkPoint p = fInitialTransform.mapXY(dest.point.x(), dest.point.y()); pdfDest->appendScalar(p.x()); pdfDest->appendScalar(p.y()); pdfDest->appendInt(0); // Leave zoom unchanged SkString name(static_cast(dest.nameData->data())); dict->insertObject(name, std::move(pdfDest)); } } sk_sp SkPDFDevice::makeFormXObjectFromDevice(bool alpha) { SkMatrix inverseTransform = SkMatrix::I(); if (!fInitialTransform.isIdentity()) { if (!fInitialTransform.invert(&inverseTransform)) { SkDEBUGFAIL("Layer initial transform should be invertible."); inverseTransform.reset(); } } const char* colorSpace = alpha ? "DeviceGray" : nullptr; sk_sp xobject = SkPDFMakeFormXObject(this->content(), this->copyMediaBox(), this->makeResourceDict(), inverseTransform, colorSpace); // We always draw the form xobjects that we create back into the device, so // we simply preserve the font usage instead of pulling it out and merging // it back in later. this->cleanUp(); // Reset this device to have no content. this->init(); return xobject; } void SkPDFDevice::drawFormXObjectWithMask(int xObjectIndex, sk_sp mask, const SkClipStack& clipStack, SkBlendMode mode, bool invertClip) { if (!invertClip && clipStack.isEmpty(this->bounds())) { return; } sk_sp sMaskGS = SkPDFGraphicState::GetSMaskGraphicState( std::move(mask), invertClip, SkPDFGraphicState::kAlpha_SMaskMode, fDocument->canon()); SkPaint paint; paint.setBlendMode(mode); ScopedContentEntry content(this, clipStack, SkMatrix::I(), paint); if (!content.entry()) { return; } SkPDFUtils::ApplyGraphicState(addGraphicStateResource(sMaskGS.get()), content.stream()); SkPDFUtils::DrawFormXObject(xObjectIndex, content.stream()); this->clearMaskOnGraphicState(content.stream()); } SkPDFDevice::ContentEntry* SkPDFDevice::setUpContentEntry(const SkClipStack& clipStack, const SkMatrix& matrix, const SkPaint& paint, bool hasText, sk_sp* dst) { *dst = nullptr; SkBlendMode blendMode = paint.getBlendMode(); // For the following modes, we want to handle source and destination // separately, so make an object of what's already there. if (blendMode == SkBlendMode::kClear || blendMode == SkBlendMode::kSrc || blendMode == SkBlendMode::kSrcIn || blendMode == SkBlendMode::kDstIn || blendMode == SkBlendMode::kSrcOut || blendMode == SkBlendMode::kDstOut || blendMode == SkBlendMode::kSrcATop || blendMode == SkBlendMode::kDstATop || blendMode == SkBlendMode::kModulate) { if (!isContentEmpty()) { *dst = this->makeFormXObjectFromDevice(); SkASSERT(isContentEmpty()); } else if (blendMode != SkBlendMode::kSrc && blendMode != SkBlendMode::kSrcOut) { // Except for Src and SrcOut, if there isn't anything already there, // then we're done. return nullptr; } } // TODO(vandebo): Figure out how/if we can handle the following modes: // Xor, Plus. // Dst xfer mode doesn't draw source at all. if (blendMode == SkBlendMode::kDst) { return nullptr; } SkPDFDevice::ContentEntry* entry; if (fContentEntries.back() && fContentEntries.back()->fContent.bytesWritten() == 0) { entry = fContentEntries.back(); } else if (blendMode != SkBlendMode::kDstOver) { entry = fContentEntries.emplace_back(); } else { entry = fContentEntries.emplace_front(); } populateGraphicStateEntryFromPaint(matrix, clipStack, paint, hasText, &entry->fState); return entry; } void SkPDFDevice::finishContentEntry(SkBlendMode blendMode, sk_sp dst, SkPath* shape) { if (blendMode != SkBlendMode::kClear && blendMode != SkBlendMode::kSrc && blendMode != SkBlendMode::kDstOver && blendMode != SkBlendMode::kSrcIn && blendMode != SkBlendMode::kDstIn && blendMode != SkBlendMode::kSrcOut && blendMode != SkBlendMode::kDstOut && blendMode != SkBlendMode::kSrcATop && blendMode != SkBlendMode::kDstATop && blendMode != SkBlendMode::kModulate) { SkASSERT(!dst); return; } if (blendMode == SkBlendMode::kDstOver) { SkASSERT(!dst); if (fContentEntries.front()->fContent.bytesWritten() == 0) { // For DstOver, an empty content entry was inserted before the rest // of the content entries. If nothing was drawn, it needs to be // removed. fContentEntries.pop_front(); } return; } if (!dst) { SkASSERT(blendMode == SkBlendMode::kSrc || blendMode == SkBlendMode::kSrcOut); return; } SkASSERT(dst); SkASSERT(fContentEntries.count() == 1); // Changing the current content into a form-xobject will destroy the clip // objects which is fine since the xobject will already be clipped. However // if source has shape, we need to clip it too, so a copy of the clip is // saved. SkClipStack clipStack = fContentEntries.front()->fState.fClipStack; SkPaint stockPaint; sk_sp srcFormXObject; if (isContentEmpty()) { // If nothing was drawn and there's no shape, then the draw was a // no-op, but dst needs to be restored for that to be true. // If there is shape, then an empty source with Src, SrcIn, SrcOut, // DstIn, DstAtop or Modulate reduces to Clear and DstOut or SrcAtop // reduces to Dst. if (shape == nullptr || blendMode == SkBlendMode::kDstOut || blendMode == SkBlendMode::kSrcATop) { ScopedContentEntry content(this, fExistingClipStack, SkMatrix::I(), stockPaint); // TODO: addXObjectResource take sk_sp SkPDFUtils::DrawFormXObject(this->addXObjectResource(dst.get()), content.stream()); return; } else { blendMode = SkBlendMode::kClear; } } else { SkASSERT(fContentEntries.count() == 1); srcFormXObject = this->makeFormXObjectFromDevice(); } // TODO(vandebo) srcFormXObject may contain alpha, but here we want it // without alpha. if (blendMode == SkBlendMode::kSrcATop) { // TODO(vandebo): In order to properly support SrcATop we have to track // the shape of what's been drawn at all times. It's the intersection of // the non-transparent parts of the device and the outlines (shape) of // all images and devices drawn. drawFormXObjectWithMask(addXObjectResource(srcFormXObject.get()), dst, fExistingClipStack, SkBlendMode::kSrcOver, true); } else { if (shape != nullptr) { // Draw shape into a form-xobject. SkPaint filledPaint; filledPaint.setColor(SK_ColorBLACK); filledPaint.setStyle(SkPaint::kFill_Style); this->internalDrawPath(clipStack, SkMatrix::I(), *shape, filledPaint, nullptr, true); this->drawFormXObjectWithMask(this->addXObjectResource(dst.get()), this->makeFormXObjectFromDevice(), fExistingClipStack, SkBlendMode::kSrcOver, true); } else { this->drawFormXObjectWithMask(this->addXObjectResource(dst.get()), srcFormXObject, fExistingClipStack, SkBlendMode::kSrcOver, true); } } if (blendMode == SkBlendMode::kClear) { return; } else if (blendMode == SkBlendMode::kSrc || blendMode == SkBlendMode::kDstATop) { ScopedContentEntry content(this, fExistingClipStack, SkMatrix::I(), stockPaint); if (content.entry()) { SkPDFUtils::DrawFormXObject(this->addXObjectResource(srcFormXObject.get()), content.stream()); } if (blendMode == SkBlendMode::kSrc) { return; } } else if (blendMode == SkBlendMode::kSrcATop) { ScopedContentEntry content(this, fExistingClipStack, SkMatrix::I(), stockPaint); if (content.entry()) { SkPDFUtils::DrawFormXObject(this->addXObjectResource(dst.get()), content.stream()); } } SkASSERT(blendMode == SkBlendMode::kSrcIn || blendMode == SkBlendMode::kDstIn || blendMode == SkBlendMode::kSrcOut || blendMode == SkBlendMode::kDstOut || blendMode == SkBlendMode::kSrcATop || blendMode == SkBlendMode::kDstATop || blendMode == SkBlendMode::kModulate); if (blendMode == SkBlendMode::kSrcIn || blendMode == SkBlendMode::kSrcOut || blendMode == SkBlendMode::kSrcATop) { drawFormXObjectWithMask(addXObjectResource(srcFormXObject.get()), std::move(dst), fExistingClipStack, SkBlendMode::kSrcOver, blendMode == SkBlendMode::kSrcOut); return; } else { SkBlendMode mode = SkBlendMode::kSrcOver; int resourceID = addXObjectResource(dst.get()); if (blendMode == SkBlendMode::kModulate) { drawFormXObjectWithMask(addXObjectResource(srcFormXObject.get()), std::move(dst), fExistingClipStack, SkBlendMode::kSrcOver, false); mode = SkBlendMode::kMultiply; } drawFormXObjectWithMask(resourceID, std::move(srcFormXObject), fExistingClipStack, mode, blendMode == SkBlendMode::kDstOut); return; } } bool SkPDFDevice::isContentEmpty() { if (!fContentEntries.front() || fContentEntries.front()->fContent.bytesWritten() == 0) { SkASSERT(fContentEntries.count() <= 1); return true; } return false; } void SkPDFDevice::populateGraphicStateEntryFromPaint( const SkMatrix& matrix, const SkClipStack& clipStack, const SkPaint& paint, bool hasText, SkPDFDevice::GraphicStateEntry* entry) { NOT_IMPLEMENTED(paint.getPathEffect() != nullptr, false); NOT_IMPLEMENTED(paint.getMaskFilter() != nullptr, false); NOT_IMPLEMENTED(paint.getColorFilter() != nullptr, false); entry->fMatrix = matrix; entry->fClipStack = clipStack; entry->fColor = SkColorSetA(paint.getColor(), 0xFF); entry->fShaderIndex = -1; // PDF treats a shader as a color, so we only set one or the other. sk_sp pdfShader; SkShader* shader = paint.getShader(); SkColor color = paint.getColor(); if (shader) { if (SkShader::kColor_GradientType == shader->asAGradient(nullptr)) { // We don't have to set a shader just for a color. SkShader::GradientInfo gradientInfo; SkColor gradientColor = SK_ColorBLACK; gradientInfo.fColors = &gradientColor; gradientInfo.fColorOffsets = nullptr; gradientInfo.fColorCount = 1; SkAssertResult(shader->asAGradient(&gradientInfo) == SkShader::kColor_GradientType); entry->fColor = SkColorSetA(gradientColor, 0xFF); color = gradientColor; } else { // PDF positions patterns relative to the initial transform, so // we need to apply the current transform to the shader parameters. SkMatrix transform = matrix; transform.postConcat(fInitialTransform); // PDF doesn't support kClamp_TileMode, so we simulate it by making // a pattern the size of the current clip. SkRect clipStackBounds = clipStack.bounds(this->bounds()); // We need to apply the initial transform to bounds in order to get // bounds in a consistent coordinate system. fInitialTransform.mapRect(&clipStackBounds); SkIRect bounds; clipStackBounds.roundOut(&bounds); pdfShader = SkPDFMakeShader(fDocument, shader, transform, bounds, paint.getColor()); if (pdfShader.get()) { // pdfShader has been canonicalized so we can directly compare // pointers. int resourceIndex = fShaderResources.find(pdfShader.get()); if (resourceIndex < 0) { resourceIndex = fShaderResources.count(); fShaderResources.push(pdfShader.get()); pdfShader.get()->ref(); } entry->fShaderIndex = resourceIndex; } } } sk_sp newGraphicState; if (color == paint.getColor()) { newGraphicState = SkPDFGraphicState::GetGraphicStateForPaint(fDocument->canon(), paint); } else { SkPaint newPaint = paint; newPaint.setColor(color); newGraphicState = SkPDFGraphicState::GetGraphicStateForPaint(fDocument->canon(), newPaint); } int resourceIndex = addGraphicStateResource(newGraphicState.get()); entry->fGraphicStateIndex = resourceIndex; if (hasText) { entry->fTextScaleX = paint.getTextScaleX(); entry->fTextFill = paint.getStyle(); } else { entry->fTextScaleX = 0; } } int SkPDFDevice::addGraphicStateResource(SkPDFObject* gs) { // Assumes that gs has been canonicalized (so we can directly compare // pointers). int result = fGraphicStateResources.find(gs); if (result < 0) { result = fGraphicStateResources.count(); fGraphicStateResources.push(gs); gs->ref(); } return result; } int SkPDFDevice::addXObjectResource(SkPDFObject* xObject) { // TODO(halcanary): make this take a sk_sp // Assumes that xobject has been canonicalized (so we can directly compare // pointers). int result = fXObjectResources.find(xObject); if (result < 0) { result = fXObjectResources.count(); fXObjectResources.push(SkRef(xObject)); } return result; } int SkPDFDevice::getFontResourceIndex(SkTypeface* typeface, uint16_t glyphID) { sk_sp newFont = SkPDFFont::GetFontResource(fDocument->canon(), typeface, glyphID); if (!newFont) { return -1; } int resourceIndex = fFontResources.find(newFont.get()); if (resourceIndex < 0) { fDocument->registerFont(newFont.get()); resourceIndex = fFontResources.count(); fFontResources.push(newFont.release()); } return resourceIndex; } static SkSize rect_to_size(const SkRect& r) { return {r.width(), r.height()}; } static sk_sp color_filter(const SkImage* image, SkColorFilter* colorFilter) { auto surface = SkSurface::MakeRaster(SkImageInfo::MakeN32Premul(image->dimensions())); SkASSERT(surface); SkCanvas* canvas = surface->getCanvas(); canvas->clear(SK_ColorTRANSPARENT); SkPaint paint; paint.setColorFilter(sk_ref_sp(colorFilter)); canvas->drawImage(image, 0, 0, &paint); return surface->makeImageSnapshot(); } //////////////////////////////////////////////////////////////////////////////// static bool is_integer(SkScalar x) { return x == SkScalarTruncToScalar(x); } static bool is_integral(const SkRect& r) { return is_integer(r.left()) && is_integer(r.top()) && is_integer(r.right()) && is_integer(r.bottom()); } void SkPDFDevice::internalDrawImageRect(SkKeyedImage imageSubset, const SkRect* src, const SkRect& dst, const SkPaint& srcPaint, const SkMatrix& ctm) { if (this->hasEmptyClip()) { return; } if (!imageSubset) { return; } // First, figure out the src->dst transform and subset the image if needed. SkIRect bounds = imageSubset.image()->bounds(); SkRect srcRect = src ? *src : SkRect::Make(bounds); SkMatrix transform; transform.setRectToRect(srcRect, dst, SkMatrix::kFill_ScaleToFit); if (src && *src != SkRect::Make(bounds)) { if (!srcRect.intersect(SkRect::Make(bounds))) { return; } srcRect.roundOut(&bounds); transform.preTranslate(SkIntToScalar(bounds.x()), SkIntToScalar(bounds.y())); if (bounds != imageSubset.image()->bounds()) { imageSubset = imageSubset.subset(bounds); } if (!imageSubset) { return; } } // If the image is opaque and the paint's alpha is too, replace // kSrc blendmode with kSrcOver. SkPaint paint = srcPaint; if (imageSubset.image()->isOpaque()) { replace_srcmode_on_opaque_paint(&paint); } // Alpha-only images need to get their color from the shader, before // applying the colorfilter. if (imageSubset.image()->isAlphaOnly() && paint.getColorFilter()) { // must blend alpha image and shader before applying colorfilter. auto surface = SkSurface::MakeRaster(SkImageInfo::MakeN32Premul(imageSubset.image()->dimensions())); SkCanvas* canvas = surface->getCanvas(); SkPaint tmpPaint; // In the case of alpha images with shaders, the shader's coordinate // system is the image's coordiantes. tmpPaint.setShader(sk_ref_sp(paint.getShader())); tmpPaint.setColor(paint.getColor()); canvas->clear(0x00000000); canvas->drawImage(imageSubset.image().get(), 0, 0, &tmpPaint); paint.setShader(nullptr); imageSubset = SkKeyedImage(surface->makeImageSnapshot()); SkASSERT(!imageSubset.image()->isAlphaOnly()); } if (imageSubset.image()->isAlphaOnly()) { // The ColorFilter applies to the paint color/shader, not the alpha layer. SkASSERT(nullptr == paint.getColorFilter()); sk_sp mask = alpha_image_to_greyscale_image(imageSubset.image().get()); if (!mask) { return; } // PDF doesn't seem to allow masking vector graphics with an Image XObject. // Must mask with a Form XObject. sk_sp maskDevice = this->makeCongruentDevice(); { SkCanvas canvas(maskDevice); if (paint.getMaskFilter()) { // This clip prevents the mask image shader from covering // entire device if unnecessary. canvas.clipRect(this->cs().bounds(this->bounds())); canvas.concat(ctm); SkPaint tmpPaint; tmpPaint.setShader(mask->makeShader(&transform)); tmpPaint.setMaskFilter(sk_ref_sp(paint.getMaskFilter())); canvas.drawRect(dst, tmpPaint); } else { canvas.concat(ctm); if (src && !is_integral(*src)) { canvas.clipRect(dst); } canvas.concat(transform); canvas.drawImage(mask, 0, 0); } } if (!ctm.isIdentity() && paint.getShader()) { transform_shader(&paint, ctm); // Since we are using identity matrix. } ScopedContentEntry content(this, this->cs(), SkMatrix::I(), paint); if (!content.entry()) { return; } this->addSMaskGraphicState(std::move(maskDevice), content.stream()); SkPDFUtils::AppendRectangle(SkRect::Make(fPageSize), content.stream()); SkPDFUtils::PaintPath(SkPaint::kFill_Style, SkPath::kWinding_FillType, content.stream()); this->clearMaskOnGraphicState(content.stream()); return; } if (paint.getMaskFilter()) { paint.setShader(imageSubset.image()->makeShader(&transform)); SkPath path; path.addRect(dst); // handles non-integral clipping. this->internalDrawPath(this->cs(), this->ctm(), path, paint, nullptr, true); return; } transform.postConcat(ctm); bool needToRestore = false; if (src && !is_integral(*src)) { // Need sub-pixel clipping to fix https://bug.skia.org/4374 this->cs().save(); this->cs().clipRect(dst, ctm, SkClipOp::kIntersect, true); needToRestore = true; } SK_AT_SCOPE_EXIT(if (needToRestore) { this->cs().restore(); }); #ifdef SK_PDF_IMAGE_STATS gDrawImageCalls.fetch_add(1); #endif SkMatrix matrix = transform; // Rasterize the bitmap using perspective in a new bitmap. if (transform.hasPerspective()) { // Transform the bitmap in the new space, without taking into // account the initial transform. SkPath perspectiveOutline; SkRect imageBounds = SkRect::Make(imageSubset.image()->bounds()); perspectiveOutline.addRect(imageBounds); perspectiveOutline.transform(transform); // TODO(edisonn): perf - use current clip too. // Retrieve the bounds of the new shape. SkRect bounds = perspectiveOutline.getBounds(); // Transform the bitmap in the new space, taking into // account the initial transform. SkMatrix total = transform; total.postConcat(fInitialTransform); SkPath physicalPerspectiveOutline; physicalPerspectiveOutline.addRect(imageBounds); physicalPerspectiveOutline.transform(total); SkRect physicalPerspectiveBounds = physicalPerspectiveOutline.getBounds(); SkScalar scaleX = physicalPerspectiveBounds.width() / bounds.width(); SkScalar scaleY = physicalPerspectiveBounds.height() / bounds.height(); // TODO(edisonn): A better approach would be to use a bitmap shader // (in clamp mode) and draw a rect over the entire bounding box. Then // intersect perspectiveOutline to the clip. That will avoid introducing // alpha to the image while still giving good behavior at the edge of // the image. Avoiding alpha will reduce the pdf size and generation // CPU time some. SkISize wh = rect_to_size(physicalPerspectiveBounds).toCeil(); auto surface = SkSurface::MakeRaster(SkImageInfo::MakeN32Premul(wh)); if (!surface) { return; } SkCanvas* canvas = surface->getCanvas(); canvas->clear(SK_ColorTRANSPARENT); SkScalar deltaX = bounds.left(); SkScalar deltaY = bounds.top(); SkMatrix offsetMatrix = transform; offsetMatrix.postTranslate(-deltaX, -deltaY); offsetMatrix.postScale(scaleX, scaleY); // Translate the draw in the new canvas, so we perfectly fit the // shape in the bitmap. canvas->setMatrix(offsetMatrix); canvas->drawImage(imageSubset.image(), 0, 0); // Make sure the final bits are in the bitmap. canvas->flush(); // In the new space, we use the identity matrix translated // and scaled to reflect DPI. matrix.setScale(1 / scaleX, 1 / scaleY); matrix.postTranslate(deltaX, deltaY); imageSubset = SkKeyedImage(surface->makeImageSnapshot()); if (!imageSubset) { return; } } SkMatrix scaled; // Adjust for origin flip. scaled.setScale(SK_Scalar1, -SK_Scalar1); scaled.postTranslate(0, SK_Scalar1); // Scale the image up from 1x1 to WxH. SkIRect subset = imageSubset.image()->bounds(); scaled.postScale(SkIntToScalar(subset.width()), SkIntToScalar(subset.height())); scaled.postConcat(matrix); ScopedContentEntry content(this, this->cs(), scaled, paint); if (!content.entry()) { return; } if (content.needShape()) { SkPath shape; shape.addRect(SkRect::Make(subset)); shape.transform(matrix); content.setShape(shape); } if (!content.needSource()) { return; } if (SkColorFilter* colorFilter = paint.getColorFilter()) { sk_sp img = color_filter(imageSubset.image().get(), colorFilter); imageSubset = SkKeyedImage(std::move(img)); if (!imageSubset) { return; } // TODO(halcanary): de-dupe this by caching filtered images. // (maybe in the resource cache?) } SkBitmapKey key = imageSubset.key(); sk_sp* pdfimagePtr = fDocument->canon()->fPDFBitmapMap.find(key); sk_sp pdfimage = pdfimagePtr ? *pdfimagePtr : nullptr; if (!pdfimage) { SkASSERT(imageSubset); pdfimage = SkPDFCreateBitmapObject(imageSubset.release(), fDocument->metadata().fEncodingQuality); if (!pdfimage) { return; } fDocument->serialize(pdfimage); // serialize images early. SkASSERT((key != SkBitmapKey{{0, 0, 0, 0}, 0})); fDocument->canon()->fPDFBitmapMap.set(key, pdfimage); } // TODO(halcanary): addXObjectResource() should take a sk_sp SkPDFUtils::DrawFormXObject(this->addXObjectResource(pdfimage.get()), content.stream()); } /////////////////////////////////////////////////////////////////////////////////////////////////// #include "SkSpecialImage.h" #include "SkImageFilter.h" void SkPDFDevice::drawSpecial(SkSpecialImage* srcImg, int x, int y, const SkPaint& paint, SkImage* clipImage, const SkMatrix& clipMatrix) { if (this->hasEmptyClip()) { return; } SkASSERT(!srcImg->isTextureBacked()); //TODO: clipImage support SkBitmap resultBM; SkImageFilter* filter = paint.getImageFilter(); if (filter) { SkIPoint offset = SkIPoint::Make(0, 0); SkMatrix matrix = this->ctm(); matrix.postTranslate(SkIntToScalar(-x), SkIntToScalar(-y)); const SkIRect clipBounds = this->cs().bounds(this->bounds()).roundOut().makeOffset(-x, -y); sk_sp cache(this->getImageFilterCache()); // TODO: Should PDF be operating in a specified color type/space? For now, run the filter // in the same color space as the source (this is different from all other backends). SkImageFilter::OutputProperties outputProperties(kN32_SkColorType, srcImg->getColorSpace()); SkImageFilter::Context ctx(matrix, clipBounds, cache.get(), outputProperties); sk_sp resultImg(filter->filterImage(srcImg, ctx, &offset)); if (resultImg) { SkPaint tmpUnfiltered(paint); tmpUnfiltered.setImageFilter(nullptr); if (resultImg->getROPixels(&resultBM)) { this->drawSprite(resultBM, x + offset.x(), y + offset.y(), tmpUnfiltered); } } } else { if (srcImg->getROPixels(&resultBM)) { this->drawSprite(resultBM, x, y, paint); } } } sk_sp SkPDFDevice::makeSpecial(const SkBitmap& bitmap) { return SkSpecialImage::MakeFromRaster(bitmap.bounds(), bitmap); } sk_sp SkPDFDevice::makeSpecial(const SkImage* image) { // TODO: See comment above in drawSpecial. The color mode we use for decode should be driven // by the destination where we're going to draw thing thing (ie this device). But we don't have // a color space, so we always decode in legacy mode for now. SkColorSpace* legacyColorSpace = nullptr; return SkSpecialImage::MakeFromImage(image->bounds(), image->makeNonTextureImage(), legacyColorSpace); } sk_sp SkPDFDevice::snapSpecial() { return nullptr; } SkImageFilterCache* SkPDFDevice::getImageFilterCache() { // We always return a transient cache, so it is freed after each // filter traversal. return SkImageFilterCache::Create(SkImageFilterCache::kDefaultTransientSize); }