/* * Copyright 2015 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkCodec.h" #include "SkCodecPriv.h" #include "SkMath.h" #include "SkSampledCodec.h" #include "SkSampler.h" #include "SkTemplates.h" SkSampledCodec::SkSampledCodec(SkCodec* codec) : INHERITED(codec) {} SkISize SkSampledCodec::accountForNativeScaling(int* sampleSizePtr, int* nativeSampleSize) const { SkISize preSampledSize = this->codec()->getInfo().dimensions(); int sampleSize = *sampleSizePtr; SkASSERT(sampleSize > 1); if (nativeSampleSize) { *nativeSampleSize = 1; } // Only JPEG supports native downsampling. if (this->codec()->getEncodedFormat() == kJPEG_SkEncodedFormat) { // See if libjpeg supports this scale directly switch (sampleSize) { case 2: case 4: case 8: // This class does not need to do any sampling. *sampleSizePtr = 1; return this->codec()->getScaledDimensions(get_scale_from_sample_size(sampleSize)); default: break; } // Check if sampleSize is a multiple of something libjpeg can support. int remainder; const int sampleSizes[] = { 8, 4, 2 }; for (int supportedSampleSize : sampleSizes) { int actualSampleSize; SkTDivMod(sampleSize, supportedSampleSize, &actualSampleSize, &remainder); if (0 == remainder) { float scale = get_scale_from_sample_size(supportedSampleSize); // this->codec() will scale to this size. preSampledSize = this->codec()->getScaledDimensions(scale); // And then this class will sample it. *sampleSizePtr = actualSampleSize; if (nativeSampleSize) { *nativeSampleSize = supportedSampleSize; } break; } } } return preSampledSize; } SkISize SkSampledCodec::onGetSampledDimensions(int sampleSize) const { const SkISize size = this->accountForNativeScaling(&sampleSize); return SkISize::Make(get_scaled_dimension(size.width(), sampleSize), get_scaled_dimension(size.height(), sampleSize)); } SkCodec::Result SkSampledCodec::onGetAndroidPixels(const SkImageInfo& info, void* pixels, size_t rowBytes, const AndroidOptions& options) { // Create an Options struct for the codec. SkCodec::Options codecOptions; codecOptions.fZeroInitialized = options.fZeroInitialized; SkIRect* subset = options.fSubset; if (!subset || subset->size() == this->codec()->getInfo().dimensions()) { if (this->codec()->dimensionsSupported(info.dimensions())) { return this->codec()->getPixels(info, pixels, rowBytes, &codecOptions, options.fColorPtr, options.fColorCount); } // If the native codec does not support the requested scale, scale by sampling. return this->sampledDecode(info, pixels, rowBytes, options); } // We are performing a subset decode. int sampleSize = options.fSampleSize; SkISize scaledSize = this->getSampledDimensions(sampleSize); if (!this->codec()->dimensionsSupported(scaledSize)) { // If the native codec does not support the requested scale, scale by sampling. return this->sampledDecode(info, pixels, rowBytes, options); } // Calculate the scaled subset bounds. int scaledSubsetX = subset->x() / sampleSize; int scaledSubsetY = subset->y() / sampleSize; int scaledSubsetWidth = info.width(); int scaledSubsetHeight = info.height(); // Start the scanline decode. SkIRect scanlineSubset = SkIRect::MakeXYWH(scaledSubsetX, 0, scaledSubsetWidth, scaledSize.height()); codecOptions.fSubset = &scanlineSubset; SkCodec::Result result = this->codec()->startScanlineDecode(info.makeWH(scaledSize.width(), scaledSize.height()), &codecOptions, options.fColorPtr, options.fColorCount); if (SkCodec::kSuccess != result) { return result; } // At this point, we are only concerned with subsetting. Either no scale was // requested, or the this->codec() is handling the scale. switch (this->codec()->getScanlineOrder()) { case SkCodec::kTopDown_SkScanlineOrder: case SkCodec::kNone_SkScanlineOrder: { if (!this->codec()->skipScanlines(scaledSubsetY)) { this->codec()->fillIncompleteImage(info, pixels, rowBytes, options.fZeroInitialized, scaledSubsetHeight, 0); return SkCodec::kIncompleteInput; } int decodedLines = this->codec()->getScanlines(pixels, scaledSubsetHeight, rowBytes); if (decodedLines != scaledSubsetHeight) { return SkCodec::kIncompleteInput; } return SkCodec::kSuccess; } default: SkASSERT(false); return SkCodec::kUnimplemented; } } SkCodec::Result SkSampledCodec::sampledDecode(const SkImageInfo& info, void* pixels, size_t rowBytes, const AndroidOptions& options) { // We should only call this function when sampling. SkASSERT(options.fSampleSize > 1); // Create options struct for the codec. SkCodec::Options sampledOptions; sampledOptions.fZeroInitialized = options.fZeroInitialized; // FIXME: This was already called by onGetAndroidPixels. Can we reduce that? int sampleSize = options.fSampleSize; int nativeSampleSize; SkISize nativeSize = this->accountForNativeScaling(&sampleSize, &nativeSampleSize); // Check if there is a subset. SkIRect subset; int subsetY = 0; int subsetWidth = nativeSize.width(); int subsetHeight = nativeSize.height(); if (options.fSubset) { // We will need to know about subsetting in the y-dimension in order to use the // scanline decoder. // Update the subset to account for scaling done by this->codec(). SkIRect* subsetPtr = options.fSubset; // Do the divide ourselves, instead of calling get_scaled_dimension. If // X and Y are 0, they should remain 0, rather than being upgraded to 1 // due to being smaller than the sampleSize. const int subsetX = subsetPtr->x() / nativeSampleSize; subsetY = subsetPtr->y() / nativeSampleSize; subsetWidth = get_scaled_dimension(subsetPtr->width(), nativeSampleSize); subsetHeight = get_scaled_dimension(subsetPtr->height(), nativeSampleSize); // The scanline decoder only needs to be aware of subsetting in the x-dimension. subset.setXYWH(subsetX, 0, subsetWidth, nativeSize.height()); sampledOptions.fSubset = ⊂ } // Start the scanline decode. SkCodec::Result result = this->codec()->startScanlineDecode( info.makeWH(nativeSize.width(), nativeSize.height()), &sampledOptions, options.fColorPtr, options.fColorCount); if (SkCodec::kSuccess != result) { return result; } SkSampler* sampler = this->codec()->getSampler(true); if (!sampler) { return SkCodec::kUnimplemented; } // Since we guarantee that output dimensions are always at least one (even if the sampleSize // is greater than a given dimension), the input sampleSize is not always the sampleSize that // we use in practice. const int sampleX = subsetWidth / info.width(); const int sampleY = subsetHeight / info.height(); if (sampler->setSampleX(sampleX) != info.width()) { return SkCodec::kInvalidScale; } if (get_scaled_dimension(subsetHeight, sampleY) != info.height()) { return SkCodec::kInvalidScale; } const int samplingOffsetY = get_start_coord(sampleY); const int startY = samplingOffsetY + subsetY; int dstHeight = info.height(); switch(this->codec()->getScanlineOrder()) { case SkCodec::kTopDown_SkScanlineOrder: { if (!this->codec()->skipScanlines(startY)) { this->codec()->fillIncompleteImage(info, pixels, rowBytes, options.fZeroInitialized, dstHeight, 0); return SkCodec::kIncompleteInput; } void* pixelPtr = pixels; for (int y = 0; y < dstHeight; y++) { if (1 != this->codec()->getScanlines(pixelPtr, 1, rowBytes)) { this->codec()->fillIncompleteImage(info, pixels, rowBytes, options.fZeroInitialized, dstHeight, y + 1); return SkCodec::kIncompleteInput; } if (y < dstHeight - 1) { if (!this->codec()->skipScanlines(sampleY - 1)) { this->codec()->fillIncompleteImage(info, pixels, rowBytes, options.fZeroInitialized, dstHeight, y + 1); return SkCodec::kIncompleteInput; } } pixelPtr = SkTAddOffset(pixelPtr, rowBytes); } return SkCodec::kSuccess; } case SkCodec::kOutOfOrder_SkScanlineOrder: case SkCodec::kBottomUp_SkScanlineOrder: { // Note that these modes do not support subsetting. SkASSERT(0 == subsetY && nativeSize.height() == subsetHeight); int y; for (y = 0; y < nativeSize.height(); y++) { int srcY = this->codec()->nextScanline(); if (is_coord_necessary(srcY, sampleY, dstHeight)) { void* pixelPtr = SkTAddOffset(pixels, rowBytes * get_dst_coord(srcY, sampleY)); if (1 != this->codec()->getScanlines(pixelPtr, 1, rowBytes)) { break; } } else { if (!this->codec()->skipScanlines(1)) { break; } } } if (nativeSize.height() == y) { return SkCodec::kSuccess; } // We handle filling uninitialized memory here instead of using this->codec(). // this->codec() does not know that we are sampling. const uint32_t fillValue = this->codec()->getFillValue(info.colorType()); const SkImageInfo fillInfo = info.makeWH(info.width(), 1); for (; y < nativeSize.height(); y++) { int srcY = this->codec()->outputScanline(y); if (!is_coord_necessary(srcY, sampleY, dstHeight)) { continue; } void* rowPtr = SkTAddOffset(pixels, rowBytes * get_dst_coord(srcY, sampleY)); SkSampler::Fill(fillInfo, rowPtr, rowBytes, fillValue, options.fZeroInitialized); } return SkCodec::kIncompleteInput; } case SkCodec::kNone_SkScanlineOrder: { const int linesNeeded = subsetHeight - samplingOffsetY; SkAutoTMalloc storage(linesNeeded * rowBytes); uint8_t* storagePtr = storage.get(); if (!this->codec()->skipScanlines(startY)) { this->codec()->fillIncompleteImage(info, pixels, rowBytes, options.fZeroInitialized, dstHeight, 0); return SkCodec::kIncompleteInput; } int scanlines = this->codec()->getScanlines(storagePtr, linesNeeded, rowBytes); for (int y = 0; y < dstHeight; y++) { memcpy(pixels, storagePtr, info.minRowBytes()); storagePtr += sampleY * rowBytes; pixels = SkTAddOffset(pixels, rowBytes); } if (scanlines < dstHeight) { // this->codec() has already handled filling uninitialized memory. return SkCodec::kIncompleteInput; } return SkCodec::kSuccess; } default: SkASSERT(false); return SkCodec::kUnimplemented; } }