/* * 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 "src/pdf/SkPDFShader.h" #include "include/core/SkData.h" #include "include/core/SkMath.h" #include "include/core/SkScalar.h" #include "include/core/SkStream.h" #include "include/core/SkSurface.h" #include "include/docs/SkPDFDocument.h" #include "include/private/SkTPin.h" #include "include/private/SkTemplates.h" #include "src/pdf/SkPDFDevice.h" #include "src/pdf/SkPDFDocumentPriv.h" #include "src/pdf/SkPDFFormXObject.h" #include "src/pdf/SkPDFGradientShader.h" #include "src/pdf/SkPDFGraphicState.h" #include "src/pdf/SkPDFResourceDict.h" #include "src/pdf/SkPDFUtils.h" static void draw(SkCanvas* canvas, const SkImage* image, SkColor4f paintColor) { SkPaint paint(paintColor); canvas->drawImage(image, 0, 0, SkSamplingOptions(), &paint); } static SkBitmap to_bitmap(const SkImage* image) { SkBitmap bitmap; if (!SkPDFUtils::ToBitmap(image, &bitmap)) { bitmap.allocN32Pixels(image->width(), image->height()); bitmap.eraseColor(0x00000000); } return bitmap; } static void draw_matrix(SkCanvas* canvas, const SkImage* image, const SkMatrix& matrix, SkColor4f paintColor) { SkAutoCanvasRestore acr(canvas, true); canvas->concat(matrix); draw(canvas, image, paintColor); } static void draw_bitmap_matrix(SkCanvas* canvas, const SkBitmap& bm, const SkMatrix& matrix, SkColor4f paintColor) { SkAutoCanvasRestore acr(canvas, true); canvas->concat(matrix); SkPaint paint(paintColor); canvas->drawImage(bm.asImage(), 0, 0, SkSamplingOptions(), &paint); } static void fill_color_from_bitmap(SkCanvas* canvas, float left, float top, float right, float bottom, const SkBitmap& bitmap, int x, int y, float alpha) { SkRect rect{left, top, right, bottom}; if (!rect.isEmpty()) { SkColor4f color = SkColor4f::FromColor(bitmap.getColor(x, y)); SkPaint paint(SkColor4f{color.fR, color.fG, color.fB, alpha * color.fA}); canvas->drawRect(rect, paint); } } static SkMatrix scale_translate(SkScalar sx, SkScalar sy, SkScalar tx, SkScalar ty) { SkMatrix m; m.setScaleTranslate(sx, sy, tx, ty); return m; } static bool is_tiled(SkTileMode m) { return SkTileMode::kMirror == m || SkTileMode::kRepeat == m; } static SkPDFIndirectReference make_image_shader(SkPDFDocument* doc, SkMatrix finalMatrix, SkTileMode tileModesX, SkTileMode tileModesY, SkRect bBox, const SkImage* image, SkColor4f paintColor) { // The image shader pattern cell will be drawn into a separate device // in pattern cell space (no scaling on the bitmap, though there may be // translations so that all content is in the device, coordinates > 0). // Map clip bounds to shader space to ensure the device is large enough // to handle fake clamping. SkRect deviceBounds = bBox; if (!SkPDFUtils::InverseTransformBBox(finalMatrix, &deviceBounds)) { return SkPDFIndirectReference(); } SkRect bitmapBounds = SkRect::MakeSize(SkSize::Make(image->dimensions())); // For tiling modes, the bounds should be extended to include the bitmap, // otherwise the bitmap gets clipped out and the shader is empty and awful. // For clamp modes, we're only interested in the clip region, whether // or not the main bitmap is in it. if (is_tiled(tileModesX) || is_tiled(tileModesY)) { deviceBounds.join(bitmapBounds); } SkISize patternDeviceSize = {SkScalarCeilToInt(deviceBounds.width()), SkScalarCeilToInt(deviceBounds.height())}; auto patternDevice = sk_make_sp(patternDeviceSize, doc); SkCanvas canvas(patternDevice); SkRect patternBBox = SkRect::MakeSize(SkSize::Make(image->dimensions())); SkScalar width = patternBBox.width(); SkScalar height = patternBBox.height(); // Translate the canvas so that the bitmap origin is at (0, 0). canvas.translate(-deviceBounds.left(), -deviceBounds.top()); patternBBox.offset(-deviceBounds.left(), -deviceBounds.top()); // Undo the translation in the final matrix finalMatrix.preTranslate(deviceBounds.left(), deviceBounds.top()); // If the bitmap is out of bounds (i.e. clamp mode where we only see the // stretched sides), canvas will clip this out and the extraneous data // won't be saved to the PDF. draw(&canvas, image, paintColor); // Tiling is implied. First we handle mirroring. if (tileModesX == SkTileMode::kMirror) { draw_matrix(&canvas, image, scale_translate(-1, 1, 2 * width, 0), paintColor); patternBBox.fRight += width; } if (tileModesY == SkTileMode::kMirror) { draw_matrix(&canvas, image, scale_translate(1, -1, 0, 2 * height), paintColor); patternBBox.fBottom += height; } if (tileModesX == SkTileMode::kMirror && tileModesY == SkTileMode::kMirror) { draw_matrix(&canvas, image, scale_translate(-1, -1, 2 * width, 2 * height), paintColor); } // Then handle Clamping, which requires expanding the pattern canvas to // cover the entire surfaceBBox. SkBitmap bitmap; if (tileModesX == SkTileMode::kClamp || tileModesY == SkTileMode::kClamp) { // For now, the easiest way to access the colors in the corners and sides is // to just make a bitmap from the image. bitmap = to_bitmap(image); } // If both x and y are in clamp mode, we start by filling in the corners. // (Which are just a rectangles of the corner colors.) if (tileModesX == SkTileMode::kClamp && tileModesY == SkTileMode::kClamp) { SkASSERT(!bitmap.drawsNothing()); fill_color_from_bitmap(&canvas, deviceBounds.left(), deviceBounds.top(), 0, 0, bitmap, 0, 0, paintColor.fA); fill_color_from_bitmap(&canvas, width, deviceBounds.top(), deviceBounds.right(), 0, bitmap, bitmap.width() - 1, 0, paintColor.fA); fill_color_from_bitmap(&canvas, width, height, deviceBounds.right(), deviceBounds.bottom(), bitmap, bitmap.width() - 1, bitmap.height() - 1, paintColor.fA); fill_color_from_bitmap(&canvas, deviceBounds.left(), height, 0, deviceBounds.bottom(), bitmap, 0, bitmap.height() - 1, paintColor.fA); } // Then expand the left, right, top, then bottom. if (tileModesX == SkTileMode::kClamp) { SkASSERT(!bitmap.drawsNothing()); SkIRect subset = SkIRect::MakeXYWH(0, 0, 1, bitmap.height()); if (deviceBounds.left() < 0) { SkBitmap left; SkAssertResult(bitmap.extractSubset(&left, subset)); SkMatrix leftMatrix = scale_translate(-deviceBounds.left(), 1, deviceBounds.left(), 0); draw_bitmap_matrix(&canvas, left, leftMatrix, paintColor); if (tileModesY == SkTileMode::kMirror) { leftMatrix.postScale(SK_Scalar1, -SK_Scalar1); leftMatrix.postTranslate(0, 2 * height); draw_bitmap_matrix(&canvas, left, leftMatrix, paintColor); } patternBBox.fLeft = 0; } if (deviceBounds.right() > width) { SkBitmap right; subset.offset(bitmap.width() - 1, 0); SkAssertResult(bitmap.extractSubset(&right, subset)); SkMatrix rightMatrix = scale_translate(deviceBounds.right() - width, 1, width, 0); draw_bitmap_matrix(&canvas, right, rightMatrix, paintColor); if (tileModesY == SkTileMode::kMirror) { rightMatrix.postScale(SK_Scalar1, -SK_Scalar1); rightMatrix.postTranslate(0, 2 * height); draw_bitmap_matrix(&canvas, right, rightMatrix, paintColor); } patternBBox.fRight = deviceBounds.width(); } } if (tileModesX == SkTileMode::kDecal) { if (deviceBounds.left() < 0) { patternBBox.fLeft = 0; } if (deviceBounds.right() > width) { patternBBox.fRight = deviceBounds.width(); } } if (tileModesY == SkTileMode::kClamp) { SkASSERT(!bitmap.drawsNothing()); SkIRect subset = SkIRect::MakeXYWH(0, 0, bitmap.width(), 1); if (deviceBounds.top() < 0) { SkBitmap top; SkAssertResult(bitmap.extractSubset(&top, subset)); SkMatrix topMatrix = scale_translate(1, -deviceBounds.top(), 0, deviceBounds.top()); draw_bitmap_matrix(&canvas, top, topMatrix, paintColor); if (tileModesX == SkTileMode::kMirror) { topMatrix.postScale(-1, 1); topMatrix.postTranslate(2 * width, 0); draw_bitmap_matrix(&canvas, top, topMatrix, paintColor); } patternBBox.fTop = 0; } if (deviceBounds.bottom() > height) { SkBitmap bottom; subset.offset(0, bitmap.height() - 1); SkAssertResult(bitmap.extractSubset(&bottom, subset)); SkMatrix bottomMatrix = scale_translate(1, deviceBounds.bottom() - height, 0, height); draw_bitmap_matrix(&canvas, bottom, bottomMatrix, paintColor); if (tileModesX == SkTileMode::kMirror) { bottomMatrix.postScale(-1, 1); bottomMatrix.postTranslate(2 * width, 0); draw_bitmap_matrix(&canvas, bottom, bottomMatrix, paintColor); } patternBBox.fBottom = deviceBounds.height(); } } if (tileModesY == SkTileMode::kDecal) { if (deviceBounds.top() < 0) { patternBBox.fTop = 0; } if (deviceBounds.bottom() > height) { patternBBox.fBottom = deviceBounds.height(); } } auto imageShader = patternDevice->content(); std::unique_ptr resourceDict = patternDevice->makeResourceDict(); std::unique_ptr dict = SkPDFMakeDict(); SkPDFUtils::PopulateTilingPatternDict(dict.get(), patternBBox, std::move(resourceDict), finalMatrix); return SkPDFStreamOut(std::move(dict), std::move(imageShader), doc); } // Generic fallback for unsupported shaders: // * allocate a surfaceBBox-sized bitmap // * shade the whole area // * use the result as a bitmap shader static SkPDFIndirectReference make_fallback_shader(SkPDFDocument* doc, SkShader* shader, const SkMatrix& canvasTransform, const SkIRect& surfaceBBox, SkColor4f paintColor) { // TODO(vandebo) This drops SKComposeShader on the floor. We could // handle compose shader by pulling things up to a layer, drawing with // the first shader, applying the xfer mode and drawing again with the // second shader, then applying the layer to the original drawing. SkMatrix shaderTransform = as_SB(shader)->getLocalMatrix(); // surfaceBBox is in device space. While that's exactly what we // want for sizing our bitmap, we need to map it into // shader space for adjustments (to match // MakeImageShader's behavior). SkRect shaderRect = SkRect::Make(surfaceBBox); if (!SkPDFUtils::InverseTransformBBox(canvasTransform, &shaderRect)) { return SkPDFIndirectReference(); } // Clamp the bitmap size to about 1M pixels static const int kMaxBitmapArea = 1024 * 1024; SkScalar bitmapArea = (float)surfaceBBox.width() * (float)surfaceBBox.height(); SkScalar rasterScale = 1.0f; if (bitmapArea > (float)kMaxBitmapArea) { rasterScale *= SkScalarSqrt((float)kMaxBitmapArea / bitmapArea); } SkISize size = { SkTPin(SkScalarCeilToInt(rasterScale * surfaceBBox.width()), 1, kMaxBitmapArea), SkTPin(SkScalarCeilToInt(rasterScale * surfaceBBox.height()), 1, kMaxBitmapArea)}; SkSize scale = {SkIntToScalar(size.width()) / shaderRect.width(), SkIntToScalar(size.height()) / shaderRect.height()}; auto surface = SkSurface::MakeRasterN32Premul(size.width(), size.height()); SkASSERT(surface); SkCanvas* canvas = surface->getCanvas(); canvas->clear(SK_ColorTRANSPARENT); SkPaint p(paintColor); p.setShader(sk_ref_sp(shader)); canvas->scale(scale.width(), scale.height()); canvas->translate(-shaderRect.x(), -shaderRect.y()); canvas->drawPaint(p); shaderTransform.setTranslate(shaderRect.x(), shaderRect.y()); shaderTransform.preScale(1 / scale.width(), 1 / scale.height()); sk_sp image = surface->makeImageSnapshot(); SkASSERT(image); return make_image_shader(doc, SkMatrix::Concat(canvasTransform, shaderTransform), SkTileMode::kClamp, SkTileMode::kClamp, SkRect::Make(surfaceBBox), image.get(), paintColor); } static SkColor4f adjust_color(SkShader* shader, SkColor4f paintColor) { if (SkImage* img = shader->isAImage(nullptr, (SkTileMode*)nullptr)) { if (img->isAlphaOnly()) { return paintColor; } } return SkColor4f{0, 0, 0, paintColor.fA}; // only preserve the alpha. } SkPDFIndirectReference SkPDFMakeShader(SkPDFDocument* doc, SkShader* shader, const SkMatrix& canvasTransform, const SkIRect& surfaceBBox, SkColor4f paintColor) { SkASSERT(shader); SkASSERT(doc); if (SkShader::kNone_GradientType != shader->asAGradient(nullptr)) { return SkPDFGradientShader::Make(doc, shader, canvasTransform, surfaceBBox); } if (surfaceBBox.isEmpty()) { return SkPDFIndirectReference(); } SkBitmap image; SkASSERT(shader->asAGradient(nullptr) == SkShader::kNone_GradientType) ; paintColor = adjust_color(shader, paintColor); SkMatrix shaderTransform; SkTileMode imageTileModes[2]; if (SkImage* skimg = shader->isAImage(&shaderTransform, imageTileModes)) { SkMatrix finalMatrix = SkMatrix::Concat(canvasTransform, shaderTransform); SkPDFImageShaderKey key = { finalMatrix, surfaceBBox, SkBitmapKeyFromImage(skimg), {imageTileModes[0], imageTileModes[1]}, paintColor}; SkPDFIndirectReference* shaderPtr = doc->fImageShaderMap.find(key); if (shaderPtr) { return *shaderPtr; } SkPDFIndirectReference pdfShader = make_image_shader(doc, finalMatrix, imageTileModes[0], imageTileModes[1], SkRect::Make(surfaceBBox), skimg, paintColor); doc->fImageShaderMap.set(std::move(key), pdfShader); return pdfShader; } // Don't bother to de-dup fallback shader. return make_fallback_shader(doc, shader, canvasTransform, surfaceBBox, paintColor); }