src/codec/SkWebpCodec.cpp - platform/external/skia - Gitiles

 /*
  * 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 "src/codec/SkWebpCodec.h"

 #include "include/codec/SkCodecAnimation.h"
 #include "include/core/SkBitmap.h"
 #include "include/core/SkCanvas.h"
 #include "include/private/SkTemplates.h"
 #include "include/private/SkTo.h"
 #include "src/codec/SkCodecPriv.h"
 #include "src/codec/SkParseEncodedOrigin.h"
 #include "src/codec/SkSampler.h"
 #include "src/core/SkRasterPipeline.h"
 #include "src/core/SkStreamPriv.h"

 // A WebP decoder on top of (subset of) libwebp
 // For more information on WebP image format, and libwebp library, see:
 //   https://code.google.com/speed/webp/
 //   http://www.webmproject.org/code/#libwebp-webp-image-library
 //   https://chromium.googlesource.com/webm/libwebp

 // If moving libwebp out of skia source tree, path for webp headers must be
 // updated accordingly. Here, we enforce using local copy in webp sub-directory.
 #include "webp/decode.h"
 #include "webp/demux.h"
 #include "webp/encode.h"

 bool SkWebpCodec::IsWebp(const void* buf, size_t bytesRead) {
     // WEBP starts with the following:
     // RIFFXXXXWEBPVP
     // Where XXXX is unspecified.
     const char* bytes = static_cast<const char*>(buf);
     return bytesRead >= 14 && !memcmp(bytes, "RIFF", 4) && !memcmp(&bytes[8], "WEBPVP", 6);
 }

 // Parse headers of RIFF container, and check for valid Webp (VP8) content.
 // Returns an SkWebpCodec on success
 std::unique_ptr<SkCodec> SkWebpCodec::MakeFromStream(std::unique_ptr<SkStream> stream,
                                                      Result* result) {
     // Webp demux needs a contiguous data buffer.
     sk_sp<SkData> data = nullptr;
     if (stream->getMemoryBase()) {
         // It is safe to make without copy because we'll hold onto the stream.
         data = SkData::MakeWithoutCopy(stream->getMemoryBase(), stream->getLength());
     } else {
         data = SkCopyStreamToData(stream.get());

         // If we are forced to copy the stream to a data, we can go ahead and delete the stream.
         stream.reset(nullptr);
     }

     // It's a little strange that the |demux| will outlive |webpData|, though it needs the
     // pointer in |webpData| to remain valid.  This works because the pointer remains valid
     // until the SkData is freed.
     WebPData webpData = { data->bytes(), data->size() };
     WebPDemuxState state;
     SkAutoTCallVProc<WebPDemuxer, WebPDemuxDelete> demux(WebPDemuxPartial(&webpData, &state));
     switch (state) {
         case WEBP_DEMUX_PARSE_ERROR:
             *result = kInvalidInput;
             return nullptr;
         case WEBP_DEMUX_PARSING_HEADER:
             *result = kIncompleteInput;
             return nullptr;
         case WEBP_DEMUX_PARSED_HEADER:
         case WEBP_DEMUX_DONE:
             SkASSERT(demux);
             break;
     }

     const int width = WebPDemuxGetI(demux, WEBP_FF_CANVAS_WIDTH);
     const int height = WebPDemuxGetI(demux, WEBP_FF_CANVAS_HEIGHT);

     // Validate the image size that's about to be decoded.
     {
         const int64_t size = sk_64_mul(width, height);
         // now check that if we are 4-bytes per pixel, we also don't overflow
         if (!SkTFitsIn<int32_t>(size) || SkTo<int32_t>(size) > (0x7FFFFFFF >> 2)) {
             *result = kInvalidInput;
             return nullptr;
         }
     }

     std::unique_ptr<SkEncodedInfo::ICCProfile> profile = nullptr;
     {
         WebPChunkIterator chunkIterator;
         SkAutoTCallVProc<WebPChunkIterator, WebPDemuxReleaseChunkIterator> autoCI(&chunkIterator);
         if (WebPDemuxGetChunk(demux, "ICCP", 1, &chunkIterator)) {
             // FIXME: I think this could be MakeWithoutCopy
             auto chunk = SkData::MakeWithCopy(chunkIterator.chunk.bytes, chunkIterator.chunk.size);
             profile = SkEncodedInfo::ICCProfile::Make(std::move(chunk));
         }
         if (profile && profile->profile()->data_color_space != skcms_Signature_RGB) {
             profile = nullptr;
         }
     }

     SkEncodedOrigin origin = kDefault_SkEncodedOrigin;
     {
         WebPChunkIterator chunkIterator;
         SkAutoTCallVProc<WebPChunkIterator, WebPDemuxReleaseChunkIterator> autoCI(&chunkIterator);
         if (WebPDemuxGetChunk(demux, "EXIF", 1, &chunkIterator)) {
             SkParseEncodedOrigin(chunkIterator.chunk.bytes, chunkIterator.chunk.size, &origin);
         }
     }

     // Get the first frame and its "features" to determine the color and alpha types.
     WebPIterator frame;
     SkAutoTCallVProc<WebPIterator, WebPDemuxReleaseIterator> autoFrame(&frame);
     if (!WebPDemuxGetFrame(demux, 1, &frame)) {
         *result = kIncompleteInput;
         return nullptr;
     }

     WebPBitstreamFeatures features;
     switch (WebPGetFeatures(frame.fragment.bytes, frame.fragment.size, &features)) {
         case VP8_STATUS_OK:
             break;
         case VP8_STATUS_SUSPENDED:
         case VP8_STATUS_NOT_ENOUGH_DATA:
             *result = kIncompleteInput;
             return nullptr;
         default:
             *result = kInvalidInput;
             return nullptr;
     }

     const bool hasAlpha = SkToBool(frame.has_alpha)
             || frame.width != width || frame.height != height;
     SkEncodedInfo::Color color;
     SkEncodedInfo::Alpha alpha;
     switch (features.format) {
         case 0:
             // This indicates a "mixed" format.  We could see this for
             // animated webps (multiple fragments).
             // We could also guess kYUV here, but I think it makes more
             // sense to guess kBGRA which is likely closer to the final
             // output.  Otherwise, we might end up converting
             // BGRA->YUVA->BGRA.
             [[fallthrough]];
         case 2:
             // This is the lossless format (BGRA).
             if (hasAlpha) {
                 color = SkEncodedInfo::kBGRA_Color;
                 alpha = SkEncodedInfo::kUnpremul_Alpha;
             } else {
                 color = SkEncodedInfo::kBGRX_Color;
                 alpha = SkEncodedInfo::kOpaque_Alpha;
             }
             break;
         case 1:
             // This is the lossy format (YUV).
             if (hasAlpha) {
                 color = SkEncodedInfo::kYUVA_Color;
                 alpha = SkEncodedInfo::kUnpremul_Alpha;
             } else {
                 color = SkEncodedInfo::kYUV_Color;
                 alpha = SkEncodedInfo::kOpaque_Alpha;
             }
             break;
         default:
             *result = kInvalidInput;
             return nullptr;
     }


     *result = kSuccess;
     SkEncodedInfo info = SkEncodedInfo::Make(width, height, color, alpha, 8, std::move(profile));
     return std::unique_ptr<SkCodec>(new SkWebpCodec(std::move(info), std::move(stream),
                                                     demux.release(), std::move(data), origin));
 }

 static WEBP_CSP_MODE webp_decode_mode(SkColorType dstCT, bool premultiply) {
     switch (dstCT) {
         case kBGRA_8888_SkColorType:
             return premultiply ? MODE_bgrA : MODE_BGRA;
         case kRGBA_8888_SkColorType:
             return premultiply ? MODE_rgbA : MODE_RGBA;
         case kRGB_565_SkColorType:
             return MODE_RGB_565;
         default:
             return MODE_LAST;
     }
 }

 SkWebpCodec::Frame* SkWebpCodec::FrameHolder::appendNewFrame(bool hasAlpha) {
     const int i = this->size();
     fFrames.emplace_back(i, hasAlpha ? SkEncodedInfo::kUnpremul_Alpha
                                      : SkEncodedInfo::kOpaque_Alpha);
     return &fFrames[i];
 }

 bool SkWebpCodec::onGetValidSubset(SkIRect* desiredSubset) const {
     if (!desiredSubset) {
         return false;
     }

     if (!this->bounds().contains(*desiredSubset)) {
         return false;
     }

     // As stated below, libwebp snaps to even left and top. Make sure top and left are even, so we
     // decode this exact subset.
     // Leave right and bottom unmodified, so we suggest a slightly larger subset than requested.
     desiredSubset->fLeft = (desiredSubset->fLeft >> 1) << 1;
     desiredSubset->fTop = (desiredSubset->fTop >> 1) << 1;
     return true;
 }

 int SkWebpCodec::onGetRepetitionCount() {
     auto flags = WebPDemuxGetI(fDemux.get(), WEBP_FF_FORMAT_FLAGS);
     if (!(flags & ANIMATION_FLAG)) {
         return 0;
     }

     int loopCount = WebPDemuxGetI(fDemux.get(), WEBP_FF_LOOP_COUNT);
     if (0 == loopCount) {
         return kRepetitionCountInfinite;
     }

     loopCount--;
     return loopCount;
 }

 int SkWebpCodec::onGetFrameCount() {
     auto flags = WebPDemuxGetI(fDemux.get(), WEBP_FF_FORMAT_FLAGS);
     if (!(flags & ANIMATION_FLAG)) {
         return 1;
     }

     const uint32_t oldFrameCount = fFrameHolder.size();
     if (fFailed) {
         return oldFrameCount;
     }

     const uint32_t frameCount = WebPDemuxGetI(fDemux, WEBP_FF_FRAME_COUNT);
     if (oldFrameCount == frameCount) {
         // We have already parsed this.
         return frameCount;
     }

     fFrameHolder.reserve(frameCount);

     for (uint32_t i = oldFrameCount; i < frameCount; i++) {
         WebPIterator iter;
         SkAutoTCallVProc<WebPIterator, WebPDemuxReleaseIterator> autoIter(&iter);

         if (!WebPDemuxGetFrame(fDemux.get(), i + 1, &iter)) {
             fFailed = true;
             break;
         }

         // libwebp only reports complete frames of an animated image.
         SkASSERT(iter.complete);

         Frame* frame = fFrameHolder.appendNewFrame(iter.has_alpha);
         frame->setXYWH(iter.x_offset, iter.y_offset, iter.width, iter.height);
         frame->setDisposalMethod(iter.dispose_method == WEBP_MUX_DISPOSE_BACKGROUND ?
                 SkCodecAnimation::DisposalMethod::kRestoreBGColor :
                 SkCodecAnimation::DisposalMethod::kKeep);
         frame->setDuration(iter.duration);
         if (WEBP_MUX_BLEND != iter.blend_method) {
             frame->setBlend(SkCodecAnimation::Blend::kSrc);
         }
         fFrameHolder.setAlphaAndRequiredFrame(frame);
     }

     return fFrameHolder.size();

 }

 const SkFrame* SkWebpCodec::FrameHolder::onGetFrame(int i) const {
     return static_cast<const SkFrame*>(this->frame(i));
 }

 const SkWebpCodec::Frame* SkWebpCodec::FrameHolder::frame(int i) const {
     SkASSERT(i >= 0 && i < this->size());
     return &fFrames[i];
 }

 bool SkWebpCodec::onGetFrameInfo(int i, FrameInfo* frameInfo) const {
     if (i >= fFrameHolder.size()) {
         return false;
     }

     const Frame* frame = fFrameHolder.frame(i);
     if (!frame) {
         return false;
     }

     if (frameInfo) {
         // libwebp only reports fully received frames for an
         // animated image.
         frame->fillIn(frameInfo, true);
     }

     return true;
 }

 static bool is_8888(SkColorType colorType) {
     switch (colorType) {
         case kRGBA_8888_SkColorType:
         case kBGRA_8888_SkColorType:
             return true;
         default:
             return false;
     }
 }

 // Requires that the src input be unpremultiplied (or opaque).
 static void blend_line(SkColorType dstCT, void* dst,
                        SkColorType srcCT, const void* src,
                        SkAlphaType dstAt,
                        bool srcHasAlpha,
                        int width) {
     SkRasterPipeline_MemoryCtx dst_ctx = { (void*)dst, 0 },
                                src_ctx = { (void*)src, 0 };

     SkRasterPipeline_<256> p;

     p.append_load_dst(dstCT, &dst_ctx);
     if (kUnpremul_SkAlphaType == dstAt) {
         p.append(SkRasterPipeline::premul_dst);
     }

     p.append_load(srcCT, &src_ctx);
     if (srcHasAlpha) {
         p.append(SkRasterPipeline::premul);
     }

     p.append(SkRasterPipeline::srcover);

     if (kUnpremul_SkAlphaType == dstAt) {
         p.append(SkRasterPipeline::unpremul);
     }
     p.append_store(dstCT, &dst_ctx);

     p.run(0,0, width,1);
 }

 SkCodec::Result SkWebpCodec::onGetPixels(const SkImageInfo& dstInfo, void* dst, size_t rowBytes,
                                          const Options& options, int* rowsDecodedPtr) {
     const int index = options.fFrameIndex;
     SkASSERT(0 == index || index < fFrameHolder.size());
     SkASSERT(0 == index || !options.fSubset);

     WebPDecoderConfig config;
     if (0 == WebPInitDecoderConfig(&config)) {
         // ABI mismatch.
         // FIXME: New enum for this?
         return kInvalidInput;
     }

     // Free any memory associated with the buffer. Must be called last, so we declare it first.
     SkAutoTCallVProc<WebPDecBuffer, WebPFreeDecBuffer> autoFree(&(config.output));

     WebPIterator frame;
     SkAutoTCallVProc<WebPIterator, WebPDemuxReleaseIterator> autoFrame(&frame);
     // If this succeeded in onGetFrameCount(), it should succeed again here.
     SkAssertResult(WebPDemuxGetFrame(fDemux, index + 1, &frame));

     const bool independent = index == 0 ? true :
             (fFrameHolder.frame(index)->getRequiredFrame() == kNoFrame);
     // Get the frameRect.  libwebp will have already signaled an error if this is not fully
     // contained by the canvas.
     auto frameRect = SkIRect::MakeXYWH(frame.x_offset, frame.y_offset, frame.width, frame.height);
     SkASSERT(this->bounds().contains(frameRect));
     const bool frameIsSubset = frameRect != this->bounds();
     if (independent && frameIsSubset) {
         SkSampler::Fill(dstInfo, dst, rowBytes, options.fZeroInitialized);
     }

     int dstX = frameRect.x();
     int dstY = frameRect.y();
     int subsetWidth = frameRect.width();
     int subsetHeight = frameRect.height();
     if (options.fSubset) {
         SkIRect subset = *options.fSubset;
         SkASSERT(this->bounds().contains(subset));
         SkASSERT(SkIsAlign2(subset.fLeft) && SkIsAlign2(subset.fTop));
         SkASSERT(this->getValidSubset(&subset) && subset == *options.fSubset);

         if (!SkIRect::Intersects(subset, frameRect)) {
             return kSuccess;
         }

         int minXOffset = std::min(dstX, subset.x());
         int minYOffset = std::min(dstY, subset.y());
         dstX -= minXOffset;
         dstY -= minYOffset;
         frameRect.offset(-minXOffset, -minYOffset);
         subset.offset(-minXOffset, -minYOffset);

         // Just like we require that the requested subset x and y offset are even, libwebp
         // guarantees that the frame x and y offset are even (it's actually impossible to specify
         // an odd frame offset).  So we can still guarantee that the adjusted offsets are even.
         SkASSERT(SkIsAlign2(subset.fLeft) && SkIsAlign2(subset.fTop));

         SkIRect intersection;
         SkAssertResult(intersection.intersect(frameRect, subset));
         subsetWidth = intersection.width();
         subsetHeight = intersection.height();

         config.options.use_cropping = 1;
         config.options.crop_left = subset.x();
         config.options.crop_top = subset.y();
         config.options.crop_width = subsetWidth;
         config.options.crop_height = subsetHeight;
     }

     // Ignore the frame size and offset when determining if scaling is necessary.
     int scaledWidth = subsetWidth;
     int scaledHeight = subsetHeight;
     SkISize srcSize = options.fSubset ? options.fSubset->size() : this->dimensions();
     if (srcSize != dstInfo.dimensions()) {
         config.options.use_scaling = 1;

         if (frameIsSubset) {
             float scaleX = ((float) dstInfo.width()) / srcSize.width();
             float scaleY = ((float) dstInfo.height()) / srcSize.height();

             // We need to be conservative here and floor rather than round.
             // Otherwise, we may find ourselves decoding off the end of memory.
             dstX = scaleX * dstX;
             scaledWidth = scaleX * scaledWidth;
             dstY = scaleY * dstY;
             scaledHeight = scaleY * scaledHeight;
             if (0 == scaledWidth || 0 == scaledHeight) {
                 return kSuccess;
             }
         } else {
             scaledWidth = dstInfo.width();
             scaledHeight = dstInfo.height();
         }

         config.options.scaled_width = scaledWidth;
         config.options.scaled_height = scaledHeight;
     }

     const bool blendWithPrevFrame = !independent && frame.blend_method == WEBP_MUX_BLEND
         && frame.has_alpha;

     auto webpInfo = dstInfo;
     if (!frame.has_alpha) {
         webpInfo = webpInfo.makeAlphaType(kOpaque_SkAlphaType);
     } else if (this->colorXform() || blendWithPrevFrame) {
         // the colorXform and blend_line expect unpremul.
         webpInfo = webpInfo.makeAlphaType(kUnpremul_SkAlphaType);
     }
     if (this->colorXform()) {
         // Swizzling between RGBA and BGRA is zero cost in a color transform.  So when we have a
         // color transform, we should decode to whatever is easiest for libwebp, and then let the
         // color transform swizzle if necessary.
         // Lossy webp is encoded as YUV (so RGBA and BGRA are the same cost).  Lossless webp is
         // encoded as BGRA. This means decoding to BGRA is either faster or the same cost as RGBA.
         webpInfo = webpInfo.makeColorType(kBGRA_8888_SkColorType);
     }

     SkBitmap webpDst;
     if ((this->colorXform() && !is_8888(dstInfo.colorType())) || blendWithPrevFrame) {
         // We will decode the entire image and then perform the color transform.  libwebp
         // does not provide a row-by-row API.  This is a shame particularly when we do not want
         // 8888, since we will need to create another image sized buffer.
         webpDst.allocPixels(webpInfo);
     } else {
         // libwebp can decode directly into the output memory.
         webpDst.installPixels(webpInfo, dst, rowBytes);
     }

     config.output.colorspace = webp_decode_mode(webpInfo.colorType(),
             webpInfo.alphaType() == kPremul_SkAlphaType);
     config.output.is_external_memory = 1;

     config.output.u.RGBA.rgba = reinterpret_cast<uint8_t*>(webpDst.getAddr(dstX, dstY));
     config.output.u.RGBA.stride = static_cast<int>(webpDst.rowBytes());
     config.output.u.RGBA.size = webpDst.computeByteSize();

     SkAutoTCallVProc<WebPIDecoder, WebPIDelete> idec(WebPIDecode(nullptr, 0, &config));
     if (!idec) {
         return kInvalidInput;
     }

     int rowsDecoded = 0;
     SkCodec::Result result;
     switch (WebPIUpdate(idec, frame.fragment.bytes, frame.fragment.size)) {
         case VP8_STATUS_OK:
             rowsDecoded = scaledHeight;
             result = kSuccess;
             break;
         case VP8_STATUS_SUSPENDED:
             if (!WebPIDecGetRGB(idec, &rowsDecoded, nullptr, nullptr, nullptr)
                     || rowsDecoded <= 0) {
                 return kInvalidInput;
             }
             *rowsDecodedPtr = rowsDecoded + dstY;
             result = kIncompleteInput;
             break;
         default:
             return kInvalidInput;
     }

     const size_t dstBpp = dstInfo.bytesPerPixel();
     dst = SkTAddOffset<void>(dst, dstBpp * dstX + rowBytes * dstY);
     const size_t srcRowBytes = config.output.u.RGBA.stride;

     const auto dstCT = dstInfo.colorType();
     if (this->colorXform()) {
         uint32_t* xformSrc = (uint32_t*) config.output.u.RGBA.rgba;
         SkBitmap tmp;
         void* xformDst;

         if (blendWithPrevFrame) {
             // Xform into temporary bitmap big enough for one row.
             tmp.allocPixels(dstInfo.makeWH(scaledWidth, 1));
             xformDst = tmp.getPixels();
         } else {
             xformDst = dst;
         }

         for (int y = 0; y < rowsDecoded; y++) {
             this->applyColorXform(xformDst, xformSrc, scaledWidth);
             if (blendWithPrevFrame) {
                 blend_line(dstCT, dst, dstCT, xformDst,
                         dstInfo.alphaType(), frame.has_alpha, scaledWidth);
                 dst = SkTAddOffset<void>(dst, rowBytes);
             } else {
                 xformDst = SkTAddOffset<void>(xformDst, rowBytes);
             }
             xformSrc = SkTAddOffset<uint32_t>(xformSrc, srcRowBytes);
         }
     } else if (blendWithPrevFrame) {
         const uint8_t* src = config.output.u.RGBA.rgba;

         for (int y = 0; y < rowsDecoded; y++) {
             blend_line(dstCT, dst, webpDst.colorType(), src,
                     dstInfo.alphaType(), frame.has_alpha, scaledWidth);
             src = SkTAddOffset<const uint8_t>(src, srcRowBytes);
             dst = SkTAddOffset<void>(dst, rowBytes);
         }
     }

     return result;
 }

 SkWebpCodec::SkWebpCodec(SkEncodedInfo&& info, std::unique_ptr<SkStream> stream,
                          WebPDemuxer* demux, sk_sp<SkData> data, SkEncodedOrigin origin)
     : INHERITED(std::move(info), skcms_PixelFormat_BGRA_8888, std::move(stream),
                 origin)
     , fDemux(demux)
     , fData(std::move(data))
     , fFailed(false)
 {
     const auto& eInfo = this->getEncodedInfo();
     fFrameHolder.setScreenSize(eInfo.width(), eInfo.height());
 }
	/*
	* 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 "src/codec/SkWebpCodec.h"

	#include "include/codec/SkCodecAnimation.h"
	#include "include/core/SkBitmap.h"
	#include "include/core/SkCanvas.h"
	#include "include/private/SkTemplates.h"
	#include "include/private/SkTo.h"
	#include "src/codec/SkCodecPriv.h"
	#include "src/codec/SkParseEncodedOrigin.h"
	#include "src/codec/SkSampler.h"
	#include "src/core/SkRasterPipeline.h"
	#include "src/core/SkStreamPriv.h"

	// A WebP decoder on top of (subset of) libwebp
	// For more information on WebP image format, and libwebp library, see:
	// https://code.google.com/speed/webp/
	// http://www.webmproject.org/code/#libwebp-webp-image-library
	// https://chromium.googlesource.com/webm/libwebp

	// If moving libwebp out of skia source tree, path for webp headers must be
	// updated accordingly. Here, we enforce using local copy in webp sub-directory.
	#include "webp/decode.h"
	#include "webp/demux.h"
	#include "webp/encode.h"

	bool SkWebpCodec::IsWebp(const void* buf, size_t bytesRead) {
	// WEBP starts with the following:
	// RIFFXXXXWEBPVP
	// Where XXXX is unspecified.
	const char* bytes = static_cast<const char*>(buf);
	return bytesRead >= 14 && !memcmp(bytes, "RIFF", 4) && !memcmp(&bytes[8], "WEBPVP", 6);
	}

	// Parse headers of RIFF container, and check for valid Webp (VP8) content.
	// Returns an SkWebpCodec on success
	std::unique_ptr<SkCodec> SkWebpCodec::MakeFromStream(std::unique_ptr<SkStream> stream,
	Result* result) {
	// Webp demux needs a contiguous data buffer.
	sk_sp<SkData> data = nullptr;
	if (stream->getMemoryBase()) {
	// It is safe to make without copy because we'll hold onto the stream.
	data = SkData::MakeWithoutCopy(stream->getMemoryBase(), stream->getLength());
	} else {
	data = SkCopyStreamToData(stream.get());

	// If we are forced to copy the stream to a data, we can go ahead and delete the stream.
	stream.reset(nullptr);
	}

	// It's a little strange that the \|demux\| will outlive \|webpData\|, though it needs the
	// pointer in \|webpData\| to remain valid. This works because the pointer remains valid
	// until the SkData is freed.
	WebPData webpData = { data->bytes(), data->size() };
	WebPDemuxState state;
	SkAutoTCallVProc<WebPDemuxer, WebPDemuxDelete> demux(WebPDemuxPartial(&webpData, &state));
	switch (state) {
	case WEBP_DEMUX_PARSE_ERROR:
	*result = kInvalidInput;
	return nullptr;
	case WEBP_DEMUX_PARSING_HEADER:
	*result = kIncompleteInput;
	return nullptr;
	case WEBP_DEMUX_PARSED_HEADER:
	case WEBP_DEMUX_DONE:
	SkASSERT(demux);
	break;
	}

	const int width = WebPDemuxGetI(demux, WEBP_FF_CANVAS_WIDTH);
	const int height = WebPDemuxGetI(demux, WEBP_FF_CANVAS_HEIGHT);

	// Validate the image size that's about to be decoded.
	{
	const int64_t size = sk_64_mul(width, height);
	// now check that if we are 4-bytes per pixel, we also don't overflow
	if (!SkTFitsIn<int32_t>(size) \|\| SkTo<int32_t>(size) > (0x7FFFFFFF >> 2)) {
	*result = kInvalidInput;
	return nullptr;
	}
	}

	std::unique_ptr<SkEncodedInfo::ICCProfile> profile = nullptr;
	{
	WebPChunkIterator chunkIterator;
	SkAutoTCallVProc<WebPChunkIterator, WebPDemuxReleaseChunkIterator> autoCI(&chunkIterator);
	if (WebPDemuxGetChunk(demux, "ICCP", 1, &chunkIterator)) {
	// FIXME: I think this could be MakeWithoutCopy
	auto chunk = SkData::MakeWithCopy(chunkIterator.chunk.bytes, chunkIterator.chunk.size);
	profile = SkEncodedInfo::ICCProfile::Make(std::move(chunk));
	}
	if (profile && profile->profile()->data_color_space != skcms_Signature_RGB) {
	profile = nullptr;
	}
	}

	SkEncodedOrigin origin = kDefault_SkEncodedOrigin;
	{
	WebPChunkIterator chunkIterator;
	SkAutoTCallVProc<WebPChunkIterator, WebPDemuxReleaseChunkIterator> autoCI(&chunkIterator);
	if (WebPDemuxGetChunk(demux, "EXIF", 1, &chunkIterator)) {
	SkParseEncodedOrigin(chunkIterator.chunk.bytes, chunkIterator.chunk.size, &origin);
	}
	}

	// Get the first frame and its "features" to determine the color and alpha types.
	WebPIterator frame;
	SkAutoTCallVProc<WebPIterator, WebPDemuxReleaseIterator> autoFrame(&frame);
	if (!WebPDemuxGetFrame(demux, 1, &frame)) {
	*result = kIncompleteInput;
	return nullptr;
	}

	WebPBitstreamFeatures features;
	switch (WebPGetFeatures(frame.fragment.bytes, frame.fragment.size, &features)) {
	case VP8_STATUS_OK:
	break;
	case VP8_STATUS_SUSPENDED:
	case VP8_STATUS_NOT_ENOUGH_DATA:
	*result = kIncompleteInput;
	return nullptr;
	default:
	*result = kInvalidInput;
	return nullptr;
	}

	const bool hasAlpha = SkToBool(frame.has_alpha)
	\|\| frame.width != width \|\| frame.height != height;
	SkEncodedInfo::Color color;
	SkEncodedInfo::Alpha alpha;
	switch (features.format) {
	case 0:
	// This indicates a "mixed" format. We could see this for
	// animated webps (multiple fragments).
	// We could also guess kYUV here, but I think it makes more
	// sense to guess kBGRA which is likely closer to the final
	// output. Otherwise, we might end up converting
	// BGRA->YUVA->BGRA.
	[[fallthrough]];
	case 2:
	// This is the lossless format (BGRA).
	if (hasAlpha) {
	color = SkEncodedInfo::kBGRA_Color;
	alpha = SkEncodedInfo::kUnpremul_Alpha;
	} else {
	color = SkEncodedInfo::kBGRX_Color;
	alpha = SkEncodedInfo::kOpaque_Alpha;
	}
	break;
	case 1:
	// This is the lossy format (YUV).
	if (hasAlpha) {
	color = SkEncodedInfo::kYUVA_Color;
	alpha = SkEncodedInfo::kUnpremul_Alpha;
	} else {
	color = SkEncodedInfo::kYUV_Color;
	alpha = SkEncodedInfo::kOpaque_Alpha;
	}
	break;
	default:
	*result = kInvalidInput;
	return nullptr;
	}


	*result = kSuccess;
	SkEncodedInfo info = SkEncodedInfo::Make(width, height, color, alpha, 8, std::move(profile));
	return std::unique_ptr<SkCodec>(new SkWebpCodec(std::move(info), std::move(stream),
	demux.release(), std::move(data), origin));
	}

	static WEBP_CSP_MODE webp_decode_mode(SkColorType dstCT, bool premultiply) {
	switch (dstCT) {
	case kBGRA_8888_SkColorType:
	return premultiply ? MODE_bgrA : MODE_BGRA;
	case kRGBA_8888_SkColorType:
	return premultiply ? MODE_rgbA : MODE_RGBA;
	case kRGB_565_SkColorType:
	return MODE_RGB_565;
	default:
	return MODE_LAST;
	}
	}

	SkWebpCodec::Frame* SkWebpCodec::FrameHolder::appendNewFrame(bool hasAlpha) {
	const int i = this->size();
	fFrames.emplace_back(i, hasAlpha ? SkEncodedInfo::kUnpremul_Alpha
	: SkEncodedInfo::kOpaque_Alpha);
	return &fFrames[i];
	}

	bool SkWebpCodec::onGetValidSubset(SkIRect* desiredSubset) const {
	if (!desiredSubset) {
	return false;
	}

	if (!this->bounds().contains(*desiredSubset)) {
	return false;
	}

	// As stated below, libwebp snaps to even left and top. Make sure top and left are even, so we
	// decode this exact subset.
	// Leave right and bottom unmodified, so we suggest a slightly larger subset than requested.
	desiredSubset->fLeft = (desiredSubset->fLeft >> 1) << 1;
	desiredSubset->fTop = (desiredSubset->fTop >> 1) << 1;
	return true;
	}

	int SkWebpCodec::onGetRepetitionCount() {
	auto flags = WebPDemuxGetI(fDemux.get(), WEBP_FF_FORMAT_FLAGS);
	if (!(flags & ANIMATION_FLAG)) {
	return 0;
	}

	int loopCount = WebPDemuxGetI(fDemux.get(), WEBP_FF_LOOP_COUNT);
	if (0 == loopCount) {
	return kRepetitionCountInfinite;
	}

	loopCount--;
	return loopCount;
	}

	int SkWebpCodec::onGetFrameCount() {
	auto flags = WebPDemuxGetI(fDemux.get(), WEBP_FF_FORMAT_FLAGS);
	if (!(flags & ANIMATION_FLAG)) {
	return 1;
	}

	const uint32_t oldFrameCount = fFrameHolder.size();
	if (fFailed) {
	return oldFrameCount;
	}

	const uint32_t frameCount = WebPDemuxGetI(fDemux, WEBP_FF_FRAME_COUNT);
	if (oldFrameCount == frameCount) {
	// We have already parsed this.
	return frameCount;
	}

	fFrameHolder.reserve(frameCount);

	for (uint32_t i = oldFrameCount; i < frameCount; i++) {
	WebPIterator iter;
	SkAutoTCallVProc<WebPIterator, WebPDemuxReleaseIterator> autoIter(&iter);

	if (!WebPDemuxGetFrame(fDemux.get(), i + 1, &iter)) {
	fFailed = true;
	break;
	}

	// libwebp only reports complete frames of an animated image.
	SkASSERT(iter.complete);

	Frame* frame = fFrameHolder.appendNewFrame(iter.has_alpha);
	frame->setXYWH(iter.x_offset, iter.y_offset, iter.width, iter.height);
	frame->setDisposalMethod(iter.dispose_method == WEBP_MUX_DISPOSE_BACKGROUND ?
	SkCodecAnimation::DisposalMethod::kRestoreBGColor :
	SkCodecAnimation::DisposalMethod::kKeep);
	frame->setDuration(iter.duration);
	if (WEBP_MUX_BLEND != iter.blend_method) {
	frame->setBlend(SkCodecAnimation::Blend::kSrc);
	}
	fFrameHolder.setAlphaAndRequiredFrame(frame);
	}

	return fFrameHolder.size();

	}

	const SkFrame* SkWebpCodec::FrameHolder::onGetFrame(int i) const {
	return static_cast<const SkFrame*>(this->frame(i));
	}

	const SkWebpCodec::Frame* SkWebpCodec::FrameHolder::frame(int i) const {
	SkASSERT(i >= 0 && i < this->size());
	return &fFrames[i];
	}

	bool SkWebpCodec::onGetFrameInfo(int i, FrameInfo* frameInfo) const {
	if (i >= fFrameHolder.size()) {
	return false;
	}

	const Frame* frame = fFrameHolder.frame(i);
	if (!frame) {
	return false;
	}

	if (frameInfo) {
	// libwebp only reports fully received frames for an
	// animated image.
	frame->fillIn(frameInfo, true);
	}

	return true;
	}

	static bool is_8888(SkColorType colorType) {
	switch (colorType) {
	case kRGBA_8888_SkColorType:
	case kBGRA_8888_SkColorType:
	return true;
	default:
	return false;
	}
	}

	// Requires that the src input be unpremultiplied (or opaque).
	static void blend_line(SkColorType dstCT, void* dst,
	SkColorType srcCT, const void* src,
	SkAlphaType dstAt,
	bool srcHasAlpha,
	int width) {
	SkRasterPipeline_MemoryCtx dst_ctx = { (void*)dst, 0 },
	src_ctx = { (void*)src, 0 };

	SkRasterPipeline_<256> p;

	p.append_load_dst(dstCT, &dst_ctx);
	if (kUnpremul_SkAlphaType == dstAt) {
	p.append(SkRasterPipeline::premul_dst);
	}

	p.append_load(srcCT, &src_ctx);
	if (srcHasAlpha) {
	p.append(SkRasterPipeline::premul);
	}

	p.append(SkRasterPipeline::srcover);

	if (kUnpremul_SkAlphaType == dstAt) {
	p.append(SkRasterPipeline::unpremul);
	}
	p.append_store(dstCT, &dst_ctx);

	p.run(0,0, width,1);
	}

	SkCodec::Result SkWebpCodec::onGetPixels(const SkImageInfo& dstInfo, void* dst, size_t rowBytes,
	const Options& options, int* rowsDecodedPtr) {
	const int index = options.fFrameIndex;
	SkASSERT(0 == index \|\| index < fFrameHolder.size());
	SkASSERT(0 == index \|\| !options.fSubset);

	WebPDecoderConfig config;
	if (0 == WebPInitDecoderConfig(&config)) {
	// ABI mismatch.
	// FIXME: New enum for this?
	return kInvalidInput;
	}

	// Free any memory associated with the buffer. Must be called last, so we declare it first.
	SkAutoTCallVProc<WebPDecBuffer, WebPFreeDecBuffer> autoFree(&(config.output));

	WebPIterator frame;
	SkAutoTCallVProc<WebPIterator, WebPDemuxReleaseIterator> autoFrame(&frame);
	// If this succeeded in onGetFrameCount(), it should succeed again here.
	SkAssertResult(WebPDemuxGetFrame(fDemux, index + 1, &frame));

	const bool independent = index == 0 ? true :
	(fFrameHolder.frame(index)->getRequiredFrame() == kNoFrame);
	// Get the frameRect. libwebp will have already signaled an error if this is not fully
	// contained by the canvas.
	auto frameRect = SkIRect::MakeXYWH(frame.x_offset, frame.y_offset, frame.width, frame.height);
	SkASSERT(this->bounds().contains(frameRect));
	const bool frameIsSubset = frameRect != this->bounds();
	if (independent && frameIsSubset) {
	SkSampler::Fill(dstInfo, dst, rowBytes, options.fZeroInitialized);
	}

	int dstX = frameRect.x();
	int dstY = frameRect.y();
	int subsetWidth = frameRect.width();
	int subsetHeight = frameRect.height();
	if (options.fSubset) {
	SkIRect subset = *options.fSubset;
	SkASSERT(this->bounds().contains(subset));
	SkASSERT(SkIsAlign2(subset.fLeft) && SkIsAlign2(subset.fTop));
	SkASSERT(this->getValidSubset(&subset) && subset == *options.fSubset);

	if (!SkIRect::Intersects(subset, frameRect)) {
	return kSuccess;
	}

	int minXOffset = std::min(dstX, subset.x());
	int minYOffset = std::min(dstY, subset.y());
	dstX -= minXOffset;
	dstY -= minYOffset;
	frameRect.offset(-minXOffset, -minYOffset);
	subset.offset(-minXOffset, -minYOffset);

	// Just like we require that the requested subset x and y offset are even, libwebp
	// guarantees that the frame x and y offset are even (it's actually impossible to specify
	// an odd frame offset). So we can still guarantee that the adjusted offsets are even.
	SkASSERT(SkIsAlign2(subset.fLeft) && SkIsAlign2(subset.fTop));

	SkIRect intersection;
	SkAssertResult(intersection.intersect(frameRect, subset));
	subsetWidth = intersection.width();
	subsetHeight = intersection.height();

	config.options.use_cropping = 1;
	config.options.crop_left = subset.x();
	config.options.crop_top = subset.y();
	config.options.crop_width = subsetWidth;
	config.options.crop_height = subsetHeight;
	}

	// Ignore the frame size and offset when determining if scaling is necessary.
	int scaledWidth = subsetWidth;
	int scaledHeight = subsetHeight;
	SkISize srcSize = options.fSubset ? options.fSubset->size() : this->dimensions();
	if (srcSize != dstInfo.dimensions()) {
	config.options.use_scaling = 1;

	if (frameIsSubset) {
	float scaleX = ((float) dstInfo.width()) / srcSize.width();
	float scaleY = ((float) dstInfo.height()) / srcSize.height();

	// We need to be conservative here and floor rather than round.
	// Otherwise, we may find ourselves decoding off the end of memory.
	dstX = scaleX * dstX;
	scaledWidth = scaleX * scaledWidth;
	dstY = scaleY * dstY;
	scaledHeight = scaleY * scaledHeight;
	if (0 == scaledWidth \|\| 0 == scaledHeight) {
	return kSuccess;
	}
	} else {
	scaledWidth = dstInfo.width();
	scaledHeight = dstInfo.height();
	}

	config.options.scaled_width = scaledWidth;
	config.options.scaled_height = scaledHeight;
	}

	const bool blendWithPrevFrame = !independent && frame.blend_method == WEBP_MUX_BLEND
	&& frame.has_alpha;

	auto webpInfo = dstInfo;
	if (!frame.has_alpha) {
	webpInfo = webpInfo.makeAlphaType(kOpaque_SkAlphaType);
	} else if (this->colorXform() \|\| blendWithPrevFrame) {
	// the colorXform and blend_line expect unpremul.
	webpInfo = webpInfo.makeAlphaType(kUnpremul_SkAlphaType);
	}
	if (this->colorXform()) {
	// Swizzling between RGBA and BGRA is zero cost in a color transform. So when we have a
	// color transform, we should decode to whatever is easiest for libwebp, and then let the
	// color transform swizzle if necessary.
	// Lossy webp is encoded as YUV (so RGBA and BGRA are the same cost). Lossless webp is
	// encoded as BGRA. This means decoding to BGRA is either faster or the same cost as RGBA.
	webpInfo = webpInfo.makeColorType(kBGRA_8888_SkColorType);
	}

	SkBitmap webpDst;
	if ((this->colorXform() && !is_8888(dstInfo.colorType())) \|\| blendWithPrevFrame) {
	// We will decode the entire image and then perform the color transform. libwebp
	// does not provide a row-by-row API. This is a shame particularly when we do not want
	// 8888, since we will need to create another image sized buffer.
	webpDst.allocPixels(webpInfo);
	} else {
	// libwebp can decode directly into the output memory.
	webpDst.installPixels(webpInfo, dst, rowBytes);
	}

	config.output.colorspace = webp_decode_mode(webpInfo.colorType(),
	webpInfo.alphaType() == kPremul_SkAlphaType);
	config.output.is_external_memory = 1;

	config.output.u.RGBA.rgba = reinterpret_cast<uint8_t*>(webpDst.getAddr(dstX, dstY));
	config.output.u.RGBA.stride = static_cast<int>(webpDst.rowBytes());
	config.output.u.RGBA.size = webpDst.computeByteSize();

	SkAutoTCallVProc<WebPIDecoder, WebPIDelete> idec(WebPIDecode(nullptr, 0, &config));
	if (!idec) {
	return kInvalidInput;
	}

	int rowsDecoded = 0;
	SkCodec::Result result;
	switch (WebPIUpdate(idec, frame.fragment.bytes, frame.fragment.size)) {
	case VP8_STATUS_OK:
	rowsDecoded = scaledHeight;
	result = kSuccess;
	break;
	case VP8_STATUS_SUSPENDED:
	if (!WebPIDecGetRGB(idec, &rowsDecoded, nullptr, nullptr, nullptr)
	\|\| rowsDecoded <= 0) {
	return kInvalidInput;
	}
	*rowsDecodedPtr = rowsDecoded + dstY;
	result = kIncompleteInput;
	break;
	default:
	return kInvalidInput;
	}

	const size_t dstBpp = dstInfo.bytesPerPixel();
	dst = SkTAddOffset<void>(dst, dstBpp * dstX + rowBytes * dstY);
	const size_t srcRowBytes = config.output.u.RGBA.stride;

	const auto dstCT = dstInfo.colorType();
	if (this->colorXform()) {
	uint32_t* xformSrc = (uint32_t*) config.output.u.RGBA.rgba;
	SkBitmap tmp;
	void* xformDst;

	if (blendWithPrevFrame) {
	// Xform into temporary bitmap big enough for one row.
	tmp.allocPixels(dstInfo.makeWH(scaledWidth, 1));
	xformDst = tmp.getPixels();
	} else {
	xformDst = dst;
	}

	for (int y = 0; y < rowsDecoded; y++) {
	this->applyColorXform(xformDst, xformSrc, scaledWidth);
	if (blendWithPrevFrame) {
	blend_line(dstCT, dst, dstCT, xformDst,
	dstInfo.alphaType(), frame.has_alpha, scaledWidth);
	dst = SkTAddOffset<void>(dst, rowBytes);
	} else {
	xformDst = SkTAddOffset<void>(xformDst, rowBytes);
	}
	xformSrc = SkTAddOffset<uint32_t>(xformSrc, srcRowBytes);
	}
	} else if (blendWithPrevFrame) {
	const uint8_t* src = config.output.u.RGBA.rgba;

	for (int y = 0; y < rowsDecoded; y++) {
	blend_line(dstCT, dst, webpDst.colorType(), src,
	dstInfo.alphaType(), frame.has_alpha, scaledWidth);
	src = SkTAddOffset<const uint8_t>(src, srcRowBytes);
	dst = SkTAddOffset<void>(dst, rowBytes);
	}
	}

	return result;
	}

	SkWebpCodec::SkWebpCodec(SkEncodedInfo&& info, std::unique_ptr<SkStream> stream,
	WebPDemuxer* demux, sk_sp<SkData> data, SkEncodedOrigin origin)
	: INHERITED(std::move(info), skcms_PixelFormat_BGRA_8888, std::move(stream),
	origin)
	, fDemux(demux)
	, fData(std::move(data))
	, fFailed(false)
	{
	const auto& eInfo = this->getEncodedInfo();
	fFrameHolder.setScreenSize(eInfo.width(), eInfo.height());
	}