/* * Copyright 2014 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkCanvas.h" #include "SkCanvasPriv.h" #include "SkDrawShadowInfo.h" #include "SkPaintPriv.h" #include "SkPatchUtils.h" #include "SkPictureData.h" #include "SkPicturePlayback.h" #include "SkPictureRecord.h" #include "SkReadBuffer.h" #include "SkRSXform.h" #include "SkSafeMath.h" #include "SkTextBlob.h" #include "SkTDArray.h" #include "SkTypes.h" // matches old SkCanvas::SaveFlags enum LegacySaveFlags { kClipToLayer_LegacySaveFlags = 0x10, }; SkCanvas::SaveLayerFlags SkCanvasPriv::LegacySaveFlagsToSaveLayerFlags(uint32_t flags) { uint32_t layerFlags = 0; if (0 == (flags & kClipToLayer_LegacySaveFlags)) { layerFlags |= kDontClipToLayer_SaveLayerFlag; } return layerFlags; } /* * Read the next op code and chunk size from 'reader'. The returned size * is the entire size of the chunk (including the opcode). Thus, the * offset just prior to calling ReadOpAndSize + 'size' is the offset * to the next chunk's op code. This also means that the size of a chunk * with no arguments (just an opcode) will be 4. */ DrawType SkPicturePlayback::ReadOpAndSize(SkReadBuffer* reader, uint32_t* size) { uint32_t temp = reader->readInt(); uint32_t op; if (((uint8_t)temp) == temp) { // old skp file - no size information op = temp; *size = 0; } else { UNPACK_8_24(temp, op, *size); if (MASK_24 == *size) { *size = reader->readInt(); } } return (DrawType)op; } static const SkRect* get_rect_ptr(SkReadBuffer* reader, SkRect* storage) { if (reader->readBool()) { reader->readRect(storage); return storage; } else { return nullptr; } } class TextContainer { public: TextContainer(SkReadBuffer* reader, const SkPaint* paint) { if (reader->validate(paint != nullptr)) { fByteLength = reader->readInt(); fText = (const char*)reader->skip(fByteLength); if (reader->isValid()) { if (fByteLength == 0) { fCount = 0; } else { fCount = SkPaintPriv::ValidCountText(fText, fByteLength, paint->getTextEncoding()); reader->validate(fCount > 0); } } } } operator bool() const { return fCount >= 0; } size_t length() const { return fByteLength; } const void* text() const { return (const void*)fText; } unsigned count() const { return fCount; } private: size_t fByteLength = 0; const char* fText = nullptr; int fCount = -1; }; void SkPicturePlayback::draw(SkCanvas* canvas, SkPicture::AbortCallback* callback, SkReadBuffer* buffer) { AutoResetOpID aroi(this); SkASSERT(0 == fCurOffset); std::unique_ptr reader; if (buffer) { reader.reset(buffer->clone(fPictureData->opData()->bytes(), fPictureData->opData()->size())); } else { reader.reset(new SkReadBuffer(fPictureData->opData()->bytes(), fPictureData->opData()->size())); } // Record this, so we can concat w/ it if we encounter a setMatrix() SkMatrix initialMatrix = canvas->getTotalMatrix(); SkAutoCanvasRestore acr(canvas, false); while (!reader->eof()) { if (callback && callback->abort()) { return; } fCurOffset = reader->offset(); uint32_t size; DrawType op = ReadOpAndSize(reader.get(), &size); if (!reader->validate(op > UNUSED && op <= LAST_DRAWTYPE_ENUM)) { return; } this->handleOp(reader.get(), op, size, canvas, initialMatrix); } // need to propagate invalid state to the parent reader if (buffer) { buffer->validate(reader->isValid()); } } static void validate_offsetToRestore(SkReadBuffer* reader, size_t offsetToRestore) { if (offsetToRestore) { reader->validate(SkIsAlign4(offsetToRestore) && offsetToRestore >= reader->offset()); } } void SkPicturePlayback::handleOp(SkReadBuffer* reader, DrawType op, uint32_t size, SkCanvas* canvas, const SkMatrix& initialMatrix) { #define BREAK_ON_READ_ERROR(r) if (!r->isValid()) { break; } switch (op) { case NOOP: { SkASSERT(size >= 4); reader->skip(size - 4); } break; case FLUSH: canvas->flush(); break; case CLIP_PATH: { const SkPath& path = fPictureData->getPath(reader); uint32_t packed = reader->readInt(); SkClipOp clipOp = ClipParams_unpackRegionOp(reader, packed); bool doAA = ClipParams_unpackDoAA(packed); size_t offsetToRestore = reader->readInt(); validate_offsetToRestore(reader, offsetToRestore); BREAK_ON_READ_ERROR(reader); canvas->clipPath(path, clipOp, doAA); if (canvas->isClipEmpty() && offsetToRestore) { reader->skip(offsetToRestore - reader->offset()); } } break; case CLIP_REGION: { SkRegion region; reader->readRegion(®ion); uint32_t packed = reader->readInt(); SkClipOp clipOp = ClipParams_unpackRegionOp(reader, packed); size_t offsetToRestore = reader->readInt(); validate_offsetToRestore(reader, offsetToRestore); BREAK_ON_READ_ERROR(reader); canvas->clipRegion(region, clipOp); if (canvas->isClipEmpty() && offsetToRestore) { reader->skip(offsetToRestore - reader->offset()); } } break; case CLIP_RECT: { SkRect rect; reader->readRect(&rect); uint32_t packed = reader->readInt(); SkClipOp clipOp = ClipParams_unpackRegionOp(reader, packed); bool doAA = ClipParams_unpackDoAA(packed); size_t offsetToRestore = reader->readInt(); validate_offsetToRestore(reader, offsetToRestore); BREAK_ON_READ_ERROR(reader); canvas->clipRect(rect, clipOp, doAA); if (canvas->isClipEmpty() && offsetToRestore) { reader->skip(offsetToRestore - reader->offset()); } } break; case CLIP_RRECT: { SkRRect rrect; reader->readRRect(&rrect); uint32_t packed = reader->readInt(); SkClipOp clipOp = ClipParams_unpackRegionOp(reader, packed); bool doAA = ClipParams_unpackDoAA(packed); size_t offsetToRestore = reader->readInt(); validate_offsetToRestore(reader, offsetToRestore); BREAK_ON_READ_ERROR(reader); canvas->clipRRect(rrect, clipOp, doAA); if (canvas->isClipEmpty() && offsetToRestore) { reader->skip(offsetToRestore - reader->offset()); } } break; case PUSH_CULL: break; // Deprecated, safe to ignore both push and pop. case POP_CULL: break; case CONCAT: { SkMatrix matrix; reader->readMatrix(&matrix); BREAK_ON_READ_ERROR(reader); canvas->concat(matrix); break; } case DRAW_ANNOTATION: { SkRect rect; reader->readRect(&rect); SkString key; reader->readString(&key); sk_sp data = reader->readByteArrayAsData(); BREAK_ON_READ_ERROR(reader); SkASSERT(data); canvas->drawAnnotation(rect, key.c_str(), data.get()); } break; case DRAW_ARC: { const SkPaint* paint = fPictureData->getPaint(reader); SkRect rect; reader->readRect(&rect); SkScalar startAngle = reader->readScalar(); SkScalar sweepAngle = reader->readScalar(); int useCenter = reader->readInt(); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawArc(rect, startAngle, sweepAngle, SkToBool(useCenter), *paint); } } break; case DRAW_ATLAS: { const SkPaint* paint = fPictureData->getPaint(reader); const SkImage* atlas = fPictureData->getImage(reader); const uint32_t flags = reader->readUInt(); const int count = reader->readUInt(); const SkRSXform* xform = (const SkRSXform*)reader->skip(count, sizeof(SkRSXform)); const SkRect* tex = (const SkRect*)reader->skip(count, sizeof(SkRect)); const SkColor* colors = nullptr; SkBlendMode mode = SkBlendMode::kDst; if (flags & DRAW_ATLAS_HAS_COLORS) { colors = (const SkColor*)reader->skip(count, sizeof(SkColor)); mode = (SkBlendMode)reader->readUInt(); } const SkRect* cull = nullptr; if (flags & DRAW_ATLAS_HAS_CULL) { cull = (const SkRect*)reader->skip(sizeof(SkRect)); } BREAK_ON_READ_ERROR(reader); canvas->drawAtlas(atlas, xform, tex, colors, count, mode, cull, paint); } break; case DRAW_CLEAR: { auto c = reader->readInt(); BREAK_ON_READ_ERROR(reader); canvas->clear(c); } break; case DRAW_DATA: { // This opcode is now dead, just need to skip it for backwards compatibility size_t length = reader->readInt(); (void)reader->skip(length); // skip handles padding the read out to a multiple of 4 } break; case DRAW_DRAWABLE: { auto* d = fPictureData->getDrawable(reader); BREAK_ON_READ_ERROR(reader); canvas->drawDrawable(d); } break; case DRAW_DRAWABLE_MATRIX: { SkMatrix matrix; reader->readMatrix(&matrix); SkDrawable* drawable = fPictureData->getDrawable(reader); BREAK_ON_READ_ERROR(reader); canvas->drawDrawable(drawable, &matrix); } break; case DRAW_DRRECT: { const SkPaint* paint = fPictureData->getPaint(reader); SkRRect outer, inner; reader->readRRect(&outer); reader->readRRect(&inner); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawDRRect(outer, inner, *paint); } } break; case DRAW_IMAGE: { const SkPaint* paint = fPictureData->getPaint(reader); const SkImage* image = fPictureData->getImage(reader); SkPoint loc; reader->readPoint(&loc); BREAK_ON_READ_ERROR(reader); canvas->drawImage(image, loc.fX, loc.fY, paint); } break; case DRAW_IMAGE_LATTICE: { const SkPaint* paint = fPictureData->getPaint(reader); const SkImage* image = fPictureData->getImage(reader); SkCanvas::Lattice lattice; (void)SkCanvasPriv::ReadLattice(*reader, &lattice); const SkRect* dst = reader->skipT(); BREAK_ON_READ_ERROR(reader); canvas->drawImageLattice(image, lattice, *dst, paint); } break; case DRAW_IMAGE_NINE: { const SkPaint* paint = fPictureData->getPaint(reader); const SkImage* image = fPictureData->getImage(reader); SkIRect center; reader->readIRect(¢er); SkRect dst; reader->readRect(&dst); BREAK_ON_READ_ERROR(reader); canvas->drawImageNine(image, center, dst, paint); } break; case DRAW_IMAGE_RECT: { const SkPaint* paint = fPictureData->getPaint(reader); const SkImage* image = fPictureData->getImage(reader); SkRect storage; const SkRect* src = get_rect_ptr(reader, &storage); // may be null SkRect dst; reader->readRect(&dst); // required // DRAW_IMAGE_RECT_STRICT assumes this constraint, and doesn't store it SkCanvas::SrcRectConstraint constraint = SkCanvas::kStrict_SrcRectConstraint; if (DRAW_IMAGE_RECT == op) { // newer op-code stores the constraint explicitly constraint = (SkCanvas::SrcRectConstraint)reader->readInt(); } BREAK_ON_READ_ERROR(reader); canvas->legacy_drawImageRect(image, src, dst, paint, constraint); } break; case DRAW_OVAL: { const SkPaint* paint = fPictureData->getPaint(reader); SkRect rect; reader->readRect(&rect); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawOval(rect, *paint); } } break; case DRAW_PAINT: { const SkPaint* paint = fPictureData->getPaint(reader); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawPaint(*paint); } } break; case DRAW_PATCH: { const SkPaint* paint = fPictureData->getPaint(reader); const SkPoint* cubics = (const SkPoint*)reader->skip(SkPatchUtils::kNumCtrlPts, sizeof(SkPoint)); uint32_t flag = reader->readInt(); const SkColor* colors = nullptr; if (flag & DRAW_VERTICES_HAS_COLORS) { colors = (const SkColor*)reader->skip(SkPatchUtils::kNumCorners, sizeof(SkColor)); } const SkPoint* texCoords = nullptr; if (flag & DRAW_VERTICES_HAS_TEXS) { texCoords = (const SkPoint*)reader->skip(SkPatchUtils::kNumCorners, sizeof(SkPoint)); } SkBlendMode bmode = SkBlendMode::kModulate; if (flag & DRAW_VERTICES_HAS_XFER) { unsigned mode = reader->readInt(); if (mode <= (unsigned)SkBlendMode::kLastMode) { bmode = (SkBlendMode)mode; } } BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawPatch(cubics, colors, texCoords, bmode, *paint); } } break; case DRAW_PATH: { const SkPaint* paint = fPictureData->getPaint(reader); const auto& path = fPictureData->getPath(reader); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawPath(path, *paint); } } break; case DRAW_PICTURE: { const auto* pic = fPictureData->getPicture(reader); BREAK_ON_READ_ERROR(reader); canvas->drawPicture(pic); } break; case DRAW_PICTURE_MATRIX_PAINT: { const SkPaint* paint = fPictureData->getPaint(reader); SkMatrix matrix; reader->readMatrix(&matrix); const SkPicture* pic = fPictureData->getPicture(reader); BREAK_ON_READ_ERROR(reader); canvas->drawPicture(pic, &matrix, paint); } break; case DRAW_POINTS: { const SkPaint* paint = fPictureData->getPaint(reader); SkCanvas::PointMode mode = (SkCanvas::PointMode)reader->readInt(); size_t count = reader->readInt(); const SkPoint* pts = (const SkPoint*)reader->skip(count, sizeof(SkPoint)); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawPoints(mode, count, pts, *paint); } } break; case DRAW_POS_TEXT: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); size_t points = reader->readInt(); reader->validate(points == text.count()); const SkPoint* pos = (const SkPoint*)reader->skip(points, sizeof(SkPoint)); BREAK_ON_READ_ERROR(reader); if (paint && text.text()) { canvas->drawPosText(text.text(), text.length(), pos, *paint); } } break; case DRAW_POS_TEXT_TOP_BOTTOM: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); size_t points = reader->readInt(); reader->validate(points == text.count()); const SkPoint* pos = (const SkPoint*)reader->skip(points, sizeof(SkPoint)); const SkScalar top = reader->readScalar(); const SkScalar bottom = reader->readScalar(); BREAK_ON_READ_ERROR(reader); SkRect clip = canvas->getLocalClipBounds(); if (top < clip.fBottom && bottom > clip.fTop && paint && text.text()) { canvas->drawPosText(text.text(), text.length(), pos, *paint); } } break; case DRAW_POS_TEXT_H: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); size_t xCount = reader->readInt(); reader->validate(xCount == text.count()); const SkScalar constY = reader->readScalar(); const SkScalar* xpos = (const SkScalar*)reader->skip(xCount, sizeof(SkScalar)); BREAK_ON_READ_ERROR(reader); if (paint && text.text()) { canvas->drawPosTextH(text.text(), text.length(), xpos, constY, *paint); } } break; case DRAW_POS_TEXT_H_TOP_BOTTOM: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); size_t xCount = reader->readInt(); reader->validate(xCount == text.count()); const SkScalar* xpos = (const SkScalar*)reader->skip(SkSafeMath::Add(3, xCount), sizeof(SkScalar)); BREAK_ON_READ_ERROR(reader); const SkScalar top = *xpos++; const SkScalar bottom = *xpos++; const SkScalar constY = *xpos++; SkRect clip = canvas->getLocalClipBounds(); if (top < clip.fBottom && bottom > clip.fTop && paint && text.text()) { canvas->drawPosTextH(text.text(), text.length(), xpos, constY, *paint); } } break; case DRAW_RECT: { const SkPaint* paint = fPictureData->getPaint(reader); SkRect rect; reader->readRect(&rect); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawRect(rect, *paint); } } break; case DRAW_REGION: { const SkPaint* paint = fPictureData->getPaint(reader); SkRegion region; reader->readRegion(®ion); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawRegion(region, *paint); } } break; case DRAW_RRECT: { const SkPaint* paint = fPictureData->getPaint(reader); SkRRect rrect; reader->readRRect(&rrect); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawRRect(rrect, *paint); } } break; case DRAW_SHADOW_REC: { const auto& path = fPictureData->getPath(reader); SkDrawShadowRec rec; reader->readPoint3(&rec.fZPlaneParams); reader->readPoint3(&rec.fLightPos); rec.fLightRadius = reader->readScalar(); if (reader->isVersionLT(SkReadBuffer::kTwoColorDrawShadow_Version)) { SkScalar ambientAlpha = reader->readScalar(); SkScalar spotAlpha = reader->readScalar(); SkColor color = reader->read32(); rec.fAmbientColor = SkColorSetA(color, SkColorGetA(color)*ambientAlpha); rec.fSpotColor = SkColorSetA(color, SkColorGetA(color)*spotAlpha); } else { rec.fAmbientColor = reader->read32(); rec.fSpotColor = reader->read32(); } rec.fFlags = reader->read32(); BREAK_ON_READ_ERROR(reader); canvas->private_draw_shadow_rec(path, rec); } break; case DRAW_TEXT: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); SkScalar x = reader->readScalar(); SkScalar y = reader->readScalar(); BREAK_ON_READ_ERROR(reader); if (paint && text.text()) { canvas->drawText(text.text(), text.length(), x, y, *paint); } } break; case DRAW_TEXT_BLOB: { const SkPaint* paint = fPictureData->getPaint(reader); const SkTextBlob* blob = fPictureData->getTextBlob(reader); SkScalar x = reader->readScalar(); SkScalar y = reader->readScalar(); BREAK_ON_READ_ERROR(reader); if (paint) { canvas->drawTextBlob(blob, x, y, *paint); } } break; case DRAW_TEXT_TOP_BOTTOM: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); const SkScalar* ptr = (const SkScalar*)reader->skip(4 * sizeof(SkScalar)); BREAK_ON_READ_ERROR(reader); // ptr[0] == x // ptr[1] == y // ptr[2] == top // ptr[3] == bottom SkRect clip = canvas->getLocalClipBounds(); float top = ptr[2]; float bottom = ptr[3]; if (top < clip.fBottom && bottom > clip.fTop && paint && text.text()) { canvas->drawText(text.text(), text.length(), ptr[0], ptr[1], *paint); } } break; case DRAW_TEXT_ON_PATH: { const SkPaint* paint = fPictureData->getPaint(reader); TextContainer text(reader, paint); const SkPath& path = fPictureData->getPath(reader); SkMatrix matrix; reader->readMatrix(&matrix); BREAK_ON_READ_ERROR(reader); if (paint && text.text()) { canvas->drawTextOnPath(text.text(), text.length(), path, &matrix, *paint); } } break; case DRAW_TEXT_RSXFORM: { const SkPaint* paint = fPictureData->getPaint(reader); uint32_t count = reader->readUInt(); uint32_t flags = reader->readUInt(); TextContainer text(reader, paint); const SkRSXform* xform = (const SkRSXform*)reader->skip(count, sizeof(SkRSXform)); const SkRect* cull = nullptr; if (flags & DRAW_TEXT_RSXFORM_HAS_CULL) { cull = (const SkRect*)reader->skip(sizeof(SkRect)); } reader->validate(count == text.count()); BREAK_ON_READ_ERROR(reader); if (text.text()) { canvas->drawTextRSXform(text.text(), text.length(), xform, cull, *paint); } } break; case DRAW_VERTICES_OBJECT: { const SkPaint* paint = fPictureData->getPaint(reader); const SkVertices* vertices = fPictureData->getVertices(reader); const int boneCount = reader->readInt(); const SkMatrix* bones = boneCount ? (const SkMatrix*) reader->skip(boneCount, sizeof(SkMatrix)) : nullptr; SkBlendMode bmode = reader->read32LE(SkBlendMode::kLastMode); BREAK_ON_READ_ERROR(reader); if (paint && vertices) { canvas->drawVertices(vertices, bones, boneCount, bmode, *paint); } } break; case RESTORE: canvas->restore(); break; case ROTATE: { auto deg = reader->readScalar(); canvas->rotate(deg); } break; case SAVE: canvas->save(); break; case SAVE_LAYER_SAVEFLAGS_DEPRECATED: { SkRect storage; const SkRect* boundsPtr = get_rect_ptr(reader, &storage); const SkPaint* paint = fPictureData->getPaint(reader); auto flags = SkCanvasPriv::LegacySaveFlagsToSaveLayerFlags(reader->readInt()); BREAK_ON_READ_ERROR(reader); canvas->saveLayer(SkCanvas::SaveLayerRec(boundsPtr, paint, flags)); } break; case SAVE_LAYER_SAVELAYERREC: { SkCanvas::SaveLayerRec rec(nullptr, nullptr, nullptr, nullptr, nullptr, 0); SkMatrix clipMatrix; const uint32_t flatFlags = reader->readInt(); SkRect bounds; if (flatFlags & SAVELAYERREC_HAS_BOUNDS) { reader->readRect(&bounds); rec.fBounds = &bounds; } if (flatFlags & SAVELAYERREC_HAS_PAINT) { rec.fPaint = fPictureData->getPaint(reader); } if (flatFlags & SAVELAYERREC_HAS_BACKDROP) { if (const auto* paint = fPictureData->getPaint(reader)) { rec.fBackdrop = paint->getImageFilter(); } } if (flatFlags & SAVELAYERREC_HAS_FLAGS) { rec.fSaveLayerFlags = reader->readInt(); } if (flatFlags & SAVELAYERREC_HAS_CLIPMASK) { rec.fClipMask = fPictureData->getImage(reader); } if (flatFlags & SAVELAYERREC_HAS_CLIPMATRIX) { reader->readMatrix(&clipMatrix); rec.fClipMatrix = &clipMatrix; } BREAK_ON_READ_ERROR(reader); canvas->saveLayer(rec); } break; case SCALE: { SkScalar sx = reader->readScalar(); SkScalar sy = reader->readScalar(); canvas->scale(sx, sy); } break; case SET_MATRIX: { SkMatrix matrix; reader->readMatrix(&matrix); matrix.postConcat(initialMatrix); canvas->setMatrix(matrix); } break; case SKEW: { SkScalar sx = reader->readScalar(); SkScalar sy = reader->readScalar(); canvas->skew(sx, sy); } break; case TRANSLATE: { SkScalar dx = reader->readScalar(); SkScalar dy = reader->readScalar(); canvas->translate(dx, dy); } break; default: reader->validate(false); // unknown op break; } #undef BREAK_ON_READ_ERROR }