/* * 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 #include "SkPictureData.h" #include "SkPictureRecord.h" #include "SkReadBuffer.h" #include "SkTextBlob.h" #include "SkTypeface.h" #include "SkWriteBuffer.h" #if SK_SUPPORT_GPU #include "GrContext.h" #endif template int SafeCount(const T* obj) { return obj ? obj->count() : 0; } SkPictureData::SkPictureData(const SkPictInfo& info) : fInfo(info) { this->init(); } void SkPictureData::initForPlayback() const { // ensure that the paths bounds are pre-computed for (int i = 0; i < fPaths.count(); i++) { fPaths[i].updateBoundsCache(); } } SkPictureData::SkPictureData(const SkPictureRecord& record, const SkPictInfo& info, bool deepCopyOps) : fInfo(info) { this->init(); fOpData = record.opData(deepCopyOps); fContentInfo.set(record.fContentInfo); fBitmaps = record.fBitmaps; fPaints = record.fPaints; fPaths = record.fPaths; this->initForPlayback(); const SkTDArray& pictures = record.getPictureRefs(); fPictureCount = pictures.count(); if (fPictureCount > 0) { fPictureRefs = SkNEW_ARRAY(const SkPicture*, fPictureCount); for (int i = 0; i < fPictureCount; i++) { fPictureRefs[i] = pictures[i]; fPictureRefs[i]->ref(); } } // templatize to consolidate with similar picture logic? const SkTDArray& blobs = record.getTextBlobRefs(); fTextBlobCount = blobs.count(); if (fTextBlobCount > 0) { fTextBlobRefs = SkNEW_ARRAY(const SkTextBlob*, fTextBlobCount); for (int i = 0; i < fTextBlobCount; ++i) { fTextBlobRefs[i] = SkRef(blobs[i]); } } } void SkPictureData::init() { fPictureRefs = NULL; fPictureCount = 0; fTextBlobRefs = NULL; fTextBlobCount = 0; fOpData = NULL; fFactoryPlayback = NULL; } SkPictureData::~SkPictureData() { SkSafeUnref(fOpData); for (int i = 0; i < fPictureCount; i++) { fPictureRefs[i]->unref(); } SkDELETE_ARRAY(fPictureRefs); for (int i = 0; i < fTextBlobCount; i++) { fTextBlobRefs[i]->unref(); } SkDELETE_ARRAY(fTextBlobRefs); SkDELETE(fFactoryPlayback); } bool SkPictureData::containsBitmaps() const { if (fBitmaps.count() > 0) { return true; } for (int i = 0; i < fPictureCount; ++i) { if (fPictureRefs[i]->willPlayBackBitmaps()) { return true; } } return false; } /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// #include "SkStream.h" static size_t compute_chunk_size(SkFlattenable::Factory* array, int count) { size_t size = 4; // for 'count' for (int i = 0; i < count; i++) { const char* name = SkFlattenable::FactoryToName(array[i]); if (NULL == name || 0 == *name) { size += SkWStream::SizeOfPackedUInt(0); } else { size_t len = strlen(name); size += SkWStream::SizeOfPackedUInt(len); size += len; } } return size; } static void write_tag_size(SkWriteBuffer& buffer, uint32_t tag, size_t size) { buffer.writeUInt(tag); buffer.writeUInt(SkToU32(size)); } static void write_tag_size(SkWStream* stream, uint32_t tag, size_t size) { stream->write32(tag); stream->write32(SkToU32(size)); } void SkPictureData::WriteFactories(SkWStream* stream, const SkFactorySet& rec) { int count = rec.count(); SkAutoSTMalloc<16, SkFlattenable::Factory> storage(count); SkFlattenable::Factory* array = (SkFlattenable::Factory*)storage.get(); rec.copyToArray(array); size_t size = compute_chunk_size(array, count); // TODO: write_tag_size should really take a size_t write_tag_size(stream, SK_PICT_FACTORY_TAG, (uint32_t) size); SkDEBUGCODE(size_t start = stream->bytesWritten()); stream->write32(count); for (int i = 0; i < count; i++) { const char* name = SkFlattenable::FactoryToName(array[i]); if (NULL == name || 0 == *name) { stream->writePackedUInt(0); } else { size_t len = strlen(name); stream->writePackedUInt(len); stream->write(name, len); } } SkASSERT(size == (stream->bytesWritten() - start)); } void SkPictureData::WriteTypefaces(SkWStream* stream, const SkRefCntSet& rec) { int count = rec.count(); write_tag_size(stream, SK_PICT_TYPEFACE_TAG, count); SkAutoSTMalloc<16, SkTypeface*> storage(count); SkTypeface** array = (SkTypeface**)storage.get(); rec.copyToArray((SkRefCnt**)array); for (int i = 0; i < count; i++) { #ifdef SK_BUILD_FOR_UNIX array[i]->serializeForcingEmbedding(stream); #else // FIXME: Macs and Windows don't draw pixel-perfect if we embed fonts in the SKP. array[i]->serialize(stream); #endif } } void SkPictureData::flattenToBuffer(SkWriteBuffer& buffer) const { int i, n; if ((n = fBitmaps.count()) > 0) { write_tag_size(buffer, SK_PICT_BITMAP_BUFFER_TAG, n); for (i = 0; i < n; i++) { buffer.writeBitmap(fBitmaps[i]); } } if ((n = fPaints.count()) > 0) { write_tag_size(buffer, SK_PICT_PAINT_BUFFER_TAG, n); for (i = 0; i < n; i++) { buffer.writePaint(fPaints[i]); } } if ((n = fPaths.count()) > 0) { write_tag_size(buffer, SK_PICT_PATH_BUFFER_TAG, n); buffer.writeInt(n); for (int i = 0; i < n; i++) { buffer.writePath(fPaths[i]); } } if (fTextBlobCount > 0) { write_tag_size(buffer, SK_PICT_TEXTBLOB_BUFFER_TAG, fTextBlobCount); for (i = 0; i < fTextBlobCount; ++i) { fTextBlobRefs[i]->flatten(buffer); } } } void SkPictureData::serialize(SkWStream* stream, SkPixelSerializer* pixelSerializer) const { write_tag_size(stream, SK_PICT_READER_TAG, fOpData->size()); stream->write(fOpData->bytes(), fOpData->size()); if (fPictureCount > 0) { write_tag_size(stream, SK_PICT_PICTURE_TAG, fPictureCount); for (int i = 0; i < fPictureCount; i++) { fPictureRefs[i]->serialize(stream, pixelSerializer); } } // Write some of our data into a writebuffer, and then serialize that // into our stream { SkRefCntSet typefaceSet; SkFactorySet factSet; SkWriteBuffer buffer(SkWriteBuffer::kCrossProcess_Flag); buffer.setTypefaceRecorder(&typefaceSet); buffer.setFactoryRecorder(&factSet); buffer.setPixelSerializer(pixelSerializer); this->flattenToBuffer(buffer); // We have to write these two sets into the stream *before* we write // the buffer, since parsing that buffer will require that we already // have these sets available to use. WriteFactories(stream, factSet); WriteTypefaces(stream, typefaceSet); write_tag_size(stream, SK_PICT_BUFFER_SIZE_TAG, buffer.bytesWritten()); buffer.writeToStream(stream); } stream->write32(SK_PICT_EOF_TAG); } void SkPictureData::flatten(SkWriteBuffer& buffer) const { write_tag_size(buffer, SK_PICT_READER_TAG, fOpData->size()); buffer.writeByteArray(fOpData->bytes(), fOpData->size()); if (fPictureCount > 0) { write_tag_size(buffer, SK_PICT_PICTURE_TAG, fPictureCount); for (int i = 0; i < fPictureCount; i++) { fPictureRefs[i]->flatten(buffer); } } // Write this picture playback's data into a writebuffer this->flattenToBuffer(buffer); buffer.write32(SK_PICT_EOF_TAG); } /////////////////////////////////////////////////////////////////////////////// /** * Return the corresponding SkReadBuffer flags, given a set of * SkPictInfo flags. */ static uint32_t pictInfoFlagsToReadBufferFlags(uint32_t pictInfoFlags) { static const struct { uint32_t fSrc; uint32_t fDst; } gSD[] = { { SkPictInfo::kCrossProcess_Flag, SkReadBuffer::kCrossProcess_Flag }, { SkPictInfo::kScalarIsFloat_Flag, SkReadBuffer::kScalarIsFloat_Flag }, { SkPictInfo::kPtrIs64Bit_Flag, SkReadBuffer::kPtrIs64Bit_Flag }, }; uint32_t rbMask = 0; for (size_t i = 0; i < SK_ARRAY_COUNT(gSD); ++i) { if (pictInfoFlags & gSD[i].fSrc) { rbMask |= gSD[i].fDst; } } return rbMask; } bool SkPictureData::parseStreamTag(SkStream* stream, uint32_t tag, uint32_t size, SkPicture::InstallPixelRefProc proc) { /* * By the time we encounter BUFFER_SIZE_TAG, we need to have already seen * its dependents: FACTORY_TAG and TYPEFACE_TAG. These two are not required * but if they are present, they need to have been seen before the buffer. * * We assert that if/when we see either of these, that we have not yet seen * the buffer tag, because if we have, then its too-late to deal with the * factories or typefaces. */ SkDEBUGCODE(bool haveBuffer = false;) switch (tag) { case SK_PICT_READER_TAG: SkASSERT(NULL == fOpData); fOpData = SkData::NewFromStream(stream, size); if (!fOpData) { return false; } break; case SK_PICT_FACTORY_TAG: { SkASSERT(!haveBuffer); size = stream->readU32(); fFactoryPlayback = SkNEW_ARGS(SkFactoryPlayback, (size)); for (size_t i = 0; i < size; i++) { SkString str; const size_t len = stream->readPackedUInt(); str.resize(len); if (stream->read(str.writable_str(), len) != len) { return false; } fFactoryPlayback->base()[i] = SkFlattenable::NameToFactory(str.c_str()); } } break; case SK_PICT_TYPEFACE_TAG: { SkASSERT(!haveBuffer); const int count = SkToInt(size); fTFPlayback.setCount(count); for (int i = 0; i < count; i++) { SkAutoTUnref tf(SkTypeface::Deserialize(stream)); if (!tf.get()) { // failed to deserialize // fTFPlayback asserts it never has a null, so we plop in // the default here. tf.reset(SkTypeface::RefDefault()); } fTFPlayback.set(i, tf); } } break; case SK_PICT_PICTURE_TAG: { fPictureCount = size; fPictureRefs = SkNEW_ARRAY(const SkPicture*, fPictureCount); bool success = true; int i = 0; for ( ; i < fPictureCount; i++) { fPictureRefs[i] = SkPicture::CreateFromStream(stream, proc); if (NULL == fPictureRefs[i]) { success = false; break; } } if (!success) { // Delete all of the pictures that were already created (up to but excluding i): for (int j = 0; j < i; j++) { fPictureRefs[j]->unref(); } // Delete the array SkDELETE_ARRAY(fPictureRefs); fPictureCount = 0; return false; } } break; case SK_PICT_BUFFER_SIZE_TAG: { SkAutoMalloc storage(size); if (stream->read(storage.get(), size) != size) { return false; } /* Should we use SkValidatingReadBuffer instead? */ SkReadBuffer buffer(storage.get(), size); buffer.setFlags(pictInfoFlagsToReadBufferFlags(fInfo.fFlags)); buffer.setVersion(fInfo.fVersion); fFactoryPlayback->setupBuffer(buffer); fTFPlayback.setupBuffer(buffer); buffer.setBitmapDecoder(proc); while (!buffer.eof() && buffer.isValid()) { tag = buffer.readUInt(); size = buffer.readUInt(); if (!this->parseBufferTag(buffer, tag, size)) { return false; } } if (!buffer.isValid()) { return false; } SkDEBUGCODE(haveBuffer = true;) } break; } return true; // success } bool SkPictureData::parseBufferTag(SkReadBuffer& buffer, uint32_t tag, uint32_t size) { switch (tag) { case SK_PICT_BITMAP_BUFFER_TAG: { const int count = SkToInt(size); fBitmaps.reset(count); for (int i = 0; i < count; ++i) { SkBitmap* bm = &fBitmaps[i]; if (buffer.readBitmap(bm)) { bm->setImmutable(); } else { return false; } } } break; case SK_PICT_PAINT_BUFFER_TAG: { const int count = SkToInt(size); fPaints.reset(count); for (int i = 0; i < count; ++i) { buffer.readPaint(&fPaints[i]); } } break; case SK_PICT_PATH_BUFFER_TAG: if (size > 0) { const int count = buffer.readInt(); fPaths.reset(count); for (int i = 0; i < count; i++) { buffer.readPath(&fPaths[i]); } } break; case SK_PICT_TEXTBLOB_BUFFER_TAG: { if (!buffer.validate((0 == fTextBlobCount) && (NULL == fTextBlobRefs))) { return false; } fTextBlobCount = size; fTextBlobRefs = SkNEW_ARRAY(const SkTextBlob*, fTextBlobCount); bool success = true; int i = 0; for ( ; i < fTextBlobCount; i++) { fTextBlobRefs[i] = SkTextBlob::CreateFromBuffer(buffer); if (NULL == fTextBlobRefs[i]) { success = false; break; } } if (!success) { // Delete all of the blobs that were already created (up to but excluding i): for (int j = 0; j < i; j++) { fTextBlobRefs[j]->unref(); } // Delete the array SkDELETE_ARRAY(fTextBlobRefs); fTextBlobRefs = NULL; fTextBlobCount = 0; return false; } } break; case SK_PICT_READER_TAG: { SkAutoDataUnref data(SkData::NewUninitialized(size)); if (!buffer.readByteArray(data->writable_data(), size) || !buffer.validate(NULL == fOpData)) { return false; } SkASSERT(NULL == fOpData); fOpData = data.detach(); } break; case SK_PICT_PICTURE_TAG: { if (!buffer.validate((0 == fPictureCount) && (NULL == fPictureRefs))) { return false; } fPictureCount = size; fPictureRefs = SkNEW_ARRAY(const SkPicture*, fPictureCount); bool success = true; int i = 0; for ( ; i < fPictureCount; i++) { fPictureRefs[i] = SkPicture::CreateFromBuffer(buffer); if (NULL == fPictureRefs[i]) { success = false; break; } } if (!success) { // Delete all of the pictures that were already created (up to but excluding i): for (int j = 0; j < i; j++) { fPictureRefs[j]->unref(); } // Delete the array SkDELETE_ARRAY(fPictureRefs); fPictureCount = 0; return false; } } break; default: // The tag was invalid. return false; } return true; // success } SkPictureData* SkPictureData::CreateFromStream(SkStream* stream, const SkPictInfo& info, SkPicture::InstallPixelRefProc proc) { SkAutoTDelete data(SkNEW_ARGS(SkPictureData, (info))); if (!data->parseStream(stream, proc)) { return NULL; } return data.detach(); } SkPictureData* SkPictureData::CreateFromBuffer(SkReadBuffer& buffer, const SkPictInfo& info) { SkAutoTDelete data(SkNEW_ARGS(SkPictureData, (info))); buffer.setVersion(info.fVersion); if (!data->parseBuffer(buffer)) { return NULL; } return data.detach(); } bool SkPictureData::parseStream(SkStream* stream, SkPicture::InstallPixelRefProc proc) { for (;;) { uint32_t tag = stream->readU32(); if (SK_PICT_EOF_TAG == tag) { break; } uint32_t size = stream->readU32(); if (!this->parseStreamTag(stream, tag, size, proc)) { return false; // we're invalid } } return true; } bool SkPictureData::parseBuffer(SkReadBuffer& buffer) { for (;;) { uint32_t tag = buffer.readUInt(); if (SK_PICT_EOF_TAG == tag) { break; } uint32_t size = buffer.readUInt(); if (!this->parseBufferTag(buffer, tag, size)) { return false; // we're invalid } } return true; } /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// #if SK_SUPPORT_GPU bool SkPictureData::suitableForGpuRasterization(GrContext* context, const char **reason, int sampleCount) const { return fContentInfo.suitableForGpuRasterization(context, reason, sampleCount); } bool SkPictureData::suitableForGpuRasterization(GrContext* context, const char **reason, GrPixelConfig config, SkScalar dpi) const { if (context != NULL) { return this->suitableForGpuRasterization(context, reason, context->getRecommendedSampleCount(config, dpi)); } else { return this->suitableForGpuRasterization(NULL, reason); } } bool SkPictureData::suitableForLayerOptimization() const { return fContentInfo.numLayers() > 0; } #endif ///////////////////////////////////////////////////////////////////////////////