/* * Copyright 2018 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkAndroidCodec.h" #include "SkAnimatedImage.h" #include "SkCanvas.h" #include "SkCodec.h" #include "SkCodecPriv.h" #include "SkImagePriv.h" #include "SkPicture.h" #include "SkPictureRecorder.h" #include "SkPixelRef.h" #include sk_sp SkAnimatedImage::Make(std::unique_ptr codec, SkISize scaledSize, SkIRect cropRect, sk_sp postProcess) { if (!codec) { return nullptr; } auto info = codec->getInfo().makeWH(scaledSize.width(), scaledSize.height()); return Make(std::move(codec), info, cropRect, std::move(postProcess)); } sk_sp SkAnimatedImage::Make(std::unique_ptr codec, const SkImageInfo& requestedInfo, SkIRect cropRect, sk_sp postProcess) { if (!codec) { return nullptr; } auto scaledSize = requestedInfo.dimensions(); auto decodeInfo = requestedInfo; if (codec->getEncodedFormat() != SkEncodedImageFormat::kWEBP || scaledSize.width() >= decodeInfo.width() || scaledSize.height() >= decodeInfo.height()) { // Only libwebp can decode to arbitrary smaller sizes. auto dims = codec->getInfo().dimensions(); decodeInfo = decodeInfo.makeWH(dims.width(), dims.height()); } auto image = sk_sp(new SkAnimatedImage(std::move(codec), scaledSize, decodeInfo, cropRect, std::move(postProcess))); if (!image->fDisplayFrame.fBitmap.getPixels()) { // tryAllocPixels failed. return nullptr; } return image; } sk_sp SkAnimatedImage::Make(std::unique_ptr codec) { if (!codec) { return nullptr; } const auto decodeInfo = codec->getInfo(); const auto scaledSize = decodeInfo.dimensions(); const auto cropRect = SkIRect::MakeSize(scaledSize); auto image = sk_sp(new SkAnimatedImage(std::move(codec), scaledSize, decodeInfo, cropRect, nullptr)); if (!image->fDisplayFrame.fBitmap.getPixels()) { // tryAllocPixels failed. return nullptr; } SkASSERT(image->fSimple); return image; } SkAnimatedImage::SkAnimatedImage(std::unique_ptr codec, SkISize scaledSize, SkImageInfo decodeInfo, SkIRect cropRect, sk_sp postProcess) : fCodec(std::move(codec)) , fScaledSize(scaledSize) , fDecodeInfo(decodeInfo) , fCropRect(cropRect) , fPostProcess(std::move(postProcess)) , fFrameCount(fCodec->codec()->getFrameCount()) , fSimple(fScaledSize == fDecodeInfo.dimensions() && !fPostProcess && fCropRect == fDecodeInfo.bounds()) , fFinished(false) , fRepetitionCount(fCodec->codec()->getRepetitionCount()) , fRepetitionsCompleted(0) { if (!fDecodingFrame.fBitmap.tryAllocPixels(fDecodeInfo)) { return; } if (!fSimple) { fMatrix = SkMatrix::MakeTrans(-fCropRect.fLeft, -fCropRect.fTop); float scaleX = (float) fScaledSize.width() / fDecodeInfo.width(); float scaleY = (float) fScaledSize.height() / fDecodeInfo.height(); fMatrix.preConcat(SkMatrix::MakeScale(scaleX, scaleY)); } this->decodeNextFrame(); } SkAnimatedImage::~SkAnimatedImage() { } SkRect SkAnimatedImage::onGetBounds() { return SkRect::MakeIWH(fCropRect.width(), fCropRect.height()); } SkAnimatedImage::Frame::Frame() : fIndex(SkCodec::kNoFrame) {} bool SkAnimatedImage::Frame::init(const SkImageInfo& info, OnInit onInit) { if (fBitmap.getPixels()) { if (fBitmap.pixelRef()->unique()) { SkAssertResult(fBitmap.setAlphaType(info.alphaType())); return true; } // An SkCanvas provided to onDraw is still holding a reference. // Copy before we decode to ensure that we don't overwrite the // expected contents of the image. if (OnInit::kRestoreIfNecessary == onInit) { SkBitmap tmp; if (!tmp.tryAllocPixels(info)) { return false; } memcpy(tmp.getPixels(), fBitmap.getPixels(), fBitmap.computeByteSize()); using std::swap; swap(tmp, fBitmap); return true; } } return fBitmap.tryAllocPixels(info); } bool SkAnimatedImage::Frame::copyTo(Frame* dst) const { if (!dst->init(fBitmap.info(), OnInit::kNoRestore)) { return false; } memcpy(dst->fBitmap.getPixels(), fBitmap.getPixels(), fBitmap.computeByteSize()); dst->fIndex = fIndex; dst->fDisposalMethod = fDisposalMethod; return true; } void SkAnimatedImage::reset() { fFinished = false; fRepetitionsCompleted = 0; if (fDisplayFrame.fIndex != 0) { fDisplayFrame.fIndex = SkCodec::kNoFrame; this->decodeNextFrame(); } } static bool is_restore_previous(SkCodecAnimation::DisposalMethod dispose) { return SkCodecAnimation::DisposalMethod::kRestorePrevious == dispose; } int SkAnimatedImage::computeNextFrame(int current, bool* animationEnded) { SkASSERT(animationEnded != nullptr); *animationEnded = false; const int frameToDecode = current + 1; if (frameToDecode == fFrameCount - 1) { // Final frame. Check to determine whether to stop. fRepetitionsCompleted++; if (fRepetitionCount != SkCodec::kRepetitionCountInfinite && fRepetitionsCompleted > fRepetitionCount) { *animationEnded = true; } } else if (frameToDecode == fFrameCount) { return 0; } return frameToDecode; } double SkAnimatedImage::finish() { fFinished = true; fCurrentFrameDuration = kFinished; return kFinished; } int SkAnimatedImage::decodeNextFrame() { if (fFinished) { return kFinished; } bool animationEnded = false; int frameToDecode = this->computeNextFrame(fDisplayFrame.fIndex, &animationEnded); SkCodec::FrameInfo frameInfo; if (fCodec->codec()->getFrameInfo(frameToDecode, &frameInfo)) { if (!frameInfo.fFullyReceived) { SkCodecPrintf("Frame %i not fully received\n", frameToDecode); return this->finish(); } fCurrentFrameDuration = frameInfo.fDuration; } else { animationEnded = true; if (0 == frameToDecode) { // Static image. This is okay. frameInfo.fRequiredFrame = SkCodec::kNoFrame; frameInfo.fAlphaType = fCodec->getInfo().alphaType(); frameInfo.fDisposalMethod = SkCodecAnimation::DisposalMethod::kKeep; // These fields won't be read. frameInfo.fDuration = INT_MAX; frameInfo.fFullyReceived = true; fCurrentFrameDuration = kFinished; } else { SkCodecPrintf("Error getting frameInfo for frame %i\n", frameToDecode); return this->finish(); } } if (frameToDecode == fDisplayFrame.fIndex) { if (animationEnded) { return this->finish(); } return fCurrentFrameDuration; } for (Frame* frame : { &fRestoreFrame, &fDecodingFrame }) { if (frameToDecode == frame->fIndex) { using std::swap; swap(fDisplayFrame, *frame); if (animationEnded) { return this->finish(); } return fCurrentFrameDuration; } } // The following code makes an effort to avoid overwriting a frame that will // be used again. If frame |i| is_restore_previous, frame |i+1| will not // depend on frame |i|, so do not overwrite frame |i-1|, which may be needed // for frame |i+1|. // We could be even smarter about which frames to save by looking at the // entire dependency chain. SkCodec::Options options; options.fFrameIndex = frameToDecode; if (frameInfo.fRequiredFrame == SkCodec::kNoFrame) { if (is_restore_previous(frameInfo.fDisposalMethod)) { // frameToDecode will be discarded immediately after drawing, so // do not overwrite a frame which could possibly be used in the // future. if (fDecodingFrame.fIndex != SkCodec::kNoFrame && !is_restore_previous(fDecodingFrame.fDisposalMethod)) { using std::swap; swap(fDecodingFrame, fRestoreFrame); } } } else { auto validPriorFrame = [&frameInfo, &frameToDecode](const Frame& frame) { if (SkCodec::kNoFrame == frame.fIndex || is_restore_previous(frame.fDisposalMethod)) { return false; } return frame.fIndex >= frameInfo.fRequiredFrame && frame.fIndex < frameToDecode; }; if (validPriorFrame(fDecodingFrame)) { if (is_restore_previous(frameInfo.fDisposalMethod)) { // fDecodingFrame is a good frame to use for this one, but we // don't want to overwrite it. fDecodingFrame.copyTo(&fRestoreFrame); } options.fPriorFrame = fDecodingFrame.fIndex; } else if (validPriorFrame(fDisplayFrame)) { if (!fDisplayFrame.copyTo(&fDecodingFrame)) { SkCodecPrintf("Failed to allocate pixels for frame\n"); return this->finish(); } options.fPriorFrame = fDecodingFrame.fIndex; } else if (validPriorFrame(fRestoreFrame)) { if (!is_restore_previous(frameInfo.fDisposalMethod)) { using std::swap; swap(fDecodingFrame, fRestoreFrame); } else if (!fRestoreFrame.copyTo(&fDecodingFrame)) { SkCodecPrintf("Failed to restore frame\n"); return this->finish(); } options.fPriorFrame = fDecodingFrame.fIndex; } } auto alphaType = kOpaque_SkAlphaType == frameInfo.fAlphaType ? kOpaque_SkAlphaType : kPremul_SkAlphaType; auto info = fDecodeInfo.makeAlphaType(alphaType); SkBitmap* dst = &fDecodingFrame.fBitmap; if (!fDecodingFrame.init(info, Frame::OnInit::kRestoreIfNecessary)) { return this->finish(); } auto result = fCodec->codec()->getPixels(dst->info(), dst->getPixels(), dst->rowBytes(), &options); if (result != SkCodec::kSuccess) { SkCodecPrintf("error %i, frame %i of %i\n", result, frameToDecode, fFrameCount); return this->finish(); } fDecodingFrame.fIndex = frameToDecode; fDecodingFrame.fDisposalMethod = frameInfo.fDisposalMethod; using std::swap; swap(fDecodingFrame, fDisplayFrame); fDisplayFrame.fBitmap.notifyPixelsChanged(); if (animationEnded) { return this->finish(); } return fCurrentFrameDuration; } void SkAnimatedImage::onDraw(SkCanvas* canvas) { auto image = SkMakeImageFromRasterBitmap(fDisplayFrame.fBitmap, kNever_SkCopyPixelsMode); if (fSimple) { canvas->drawImage(image, 0, 0); return; } SkRect bounds = this->getBounds(); if (fPostProcess) { canvas->saveLayer(&bounds, nullptr); } { SkAutoCanvasRestore acr(canvas, fPostProcess != nullptr); canvas->concat(fMatrix); SkPaint paint; paint.setFilterQuality(kLow_SkFilterQuality); canvas->drawImage(image, 0, 0, &paint); } if (fPostProcess) { canvas->drawPicture(fPostProcess); canvas->restore(); } } void SkAnimatedImage::setRepetitionCount(int newCount) { fRepetitionCount = newCount; }